undergraduate catalog 2015 - 2016
Transcription
undergraduate catalog 2015 - 2016
UNDERGRADUATE CATALOG 2015 - 2016 www.pi.ac.ae 1 2 The Petroleum Institute Undergraduate Catalog 2015-16 Policy Regarding On-line and Print Versions of The Petroleum Institute’s Catalogs, Manuals and Handbooks Every effort has been made to provide the most accurate, up-to-date information possible in PI’s catalogs, manuals, and handbooks. Each document is revised yearly and limited numbers printed once every two years. There may be times when substantive changes are required during the academic year and between the times the documents are printed. The catalogs, manuals, and handbooks are posted to the Institute’s web site at www.pi.ac.ae. Faculty, staff, and students should consult the PI website periodically for updates hereto and any other written or oral statements, the online version and its supplements shall be deemed to deadlines and fees are published in the online version of the catalog, which is considered a supplement. The most current catalog is available online at www.pi.ac.ae/PI_STU/ro/calendar.php. The Institute reserves the right to change any of the statements herein by reasonable notice in any supplemental catalog or other 1 PI Academic Calendar 2015-2016 Fall 2015 New Student Orientation Sunday, August 18 Fall Semester Classes Begin Sunday, August 23 Add/Drop Period Begins Sunday, August 23 Last Day to Drop without Record Sunday, August 30 at 3 pm Eid Al Adha, Classes Suspended Wednesday, September 23 Thursday, September 24 Hijri New year 1437, Classes suspended Wednesday, October 14 Mid Semester Grades Due Monday, October 19 Last Day to Withdraw from Classes Thursday, November 5 Advisement Period for Spring 2016 Sunday, November 1 Thursday, November 5 Early registration for Spring 2016 Sunday, November 8 Thursday, November 12 Graduation Application Deadline for Sp/Su2016 Thursday, November 19 National Day Holiday, Classes Suspended Wednesday, December 2 Thursday, December 3 HFIT Exams Saturday, December 5 Last Day of Fall Classes Thursday, December 10 Final Exams Sunday, December 13 Thursday, December 17 Final Exams Make Up Day Saturday, December 19 Final Grades Due Tuesday, December 22 Fall Break Sunday, December 20 Thursday, January 7 Spring 2016 New Student Orientation Sunday, January 3 Spring Semester Classes Begin Sunday, January 10, 2016 Add/Drop Period Begins Sunday, January 10 Last Day to Drop without Record Sunday, January 17 at 3 pm Mid-Semester Grades Due Monday, March 7 Global Day Celebration Tuesday,March 8, Classes Suspended after 3 PM Last Day to Withdraw from Classes Thursday, March 24 Spring Break, Classes Suspended Sunday, March 27 – Thursday, April 7 Classes Resume Sunday, April 10 Advisement Period Sunday, April 10 – Thursday, April 14 Early registration for Summer/Fall Sunday, April 17-Thursday, April 21 Graduation Application Deadline for Fall2017 Thursday, April 28 2 HFIT Exams Saturday, April 30 Last Day of Spring Classes Thursday, May 5 Final Exam Days Sunday, May 8 – Thursday, May 12 Final Exam Make Up Day Saturday, May 14 Final Grades Due Tuesday, May 17 Summer 2016 Summer Session Classes/Internships Begin Sunday, May 29 Add/Drop Period Begins Sunday, May 29 Last Day to Drop without Record Monday, May 30 Mid-Session Grades Due Sunday, June 19 Last Day to Withdraw from Summer Classes Sunday, June 26 Last Day of Summer Classes Thursday, July 7 Final Exams Day Sunday, July 10 Final Grades Due Wednesday, July 13 Internships End Thursday, July 21 Internship Grades Due Wednesday, August 14 Expected Fall 2016 Classes Begin Sunday, August 21 Expected Fall2016 Break Sunday, December 18 – Thursday, January 5 HFIT Exams Saturday, December 5 Last Day of Fall Classes Thursday, December 10 Final Exams Sunday, December 13 Thursday, December 17 Final Exams Make Up Day Saturday, December 19 Final Grades Due Tuesday, December 22 Fall Break Sunday, December 20 Thursday, January 7 Notes: In the event of any changes to the Academic Calendar, an official notification will be sent by the Office of the Senior Vice President and Provost. If Make Up Class days are required, an official notification will be sent by the Office of the Senior Vice President and Provost. Islamic holidays are determined after sighting the moon. Thus, actual dates may not coincide with the dates in this calendar. In the event of loss of teaching days due to unscheduled closings, the semester(s) may be extended or Saturday classes may be required. 3 Table of Contents Academic Calendar 2015 – 2016 ..............................................................................................................................2 Telephone and E-mail Directory ..............................................................................................................................7 Overview of the Petroleum Institute ......................................................................................................................8 Outline of Accreditation History ..............................................................................................................................9 Institutional Mission Statement ................................................................................................................................9 Institutional Goals ........................................................................................................................................................10 Accreditation and Licensure ....................................................................................................................................12 Campus Facilities ..........................................................................................................................................................12 Food Outlets ..................................................................................................................................................................12 Housing and Residence Life .....................................................................................................................................12 Information Technology .............................................................................................................................................16 Library & Independent Learning Center ( ILC ) ................................................................................................18 Sports Complex ............................................................................................................................................................18 Student Centers and Lounges ................................................................................................................................18 Women in Science and Engineering Facilities ..................................................................................................18 PI Center for Excellence in Learning and Teaching (CELT) .........................................................................19 Health, Safety and Environment ............................................................................................................................19 Policy ................................................................................................................................................................................19 Commitment ..................................................................................................................................................................19 HSE Expectations .......................................................................................................................................................20 Student Success Department ................................................................................................................................20 Independent Learning Centers (ILCs) ................................................................................................................20 Counseling ......................................................................................................................................................................21 Career Services .............................................................................................................................................................21 Health Services ..............................................................................................................................................................21 Mail Service .....................................................................................................................................................................21 Public Relations ............................................................................................................................................................21 Student Records ..........................................................................................................................................................22 Privacy Rights of Students ......................................................................................................................................22 Transcripts and Other Records ..............................................................................................................................22 Release of Transcripts and Student Information ............................................................................................22 Admissions .....................................................................................................................................................................23 Admission Process ......................................................................................................................................................23 Admission Requirements .........................................................................................................................................23 Transfer Students Studying at Another Institution ........................................................................................24 Credit Awarded through Non-Traditional Sources .........................................................................................25 Placement Tests ...........................................................................................................................................................25 Readmitted Students ................................................................................................................................................26 Non-Degree Students ...............................................................................................................................................26 Declaration of a Major ...............................................................................................................................................26 Grades and Grade Point Averages .......................................................................................................................27 Grade Appeal ................................................................................................................................................................28 Repeat Provision .........................................................................................................................................................28 Grade-Point Averages ...............................................................................................................................................29 4 Quality Hours and Quality Points .........................................................................................................................29 Transfer Credit Excluded in GPA Calculation ...................................................................................................29 Credit Hours ..................................................................................................................................................................29 Honor List .......................................................................................................................................................................26 Graduation Requirements .......................................................................................................................................30 Catalog of Record ......................................................................................................................................................30 Time Limit on Study ..................................................................................................................................................30 Graduation Requirements .......................................................................................................................................30 Academic Rules and Regulations ........................................................................................................................30 Full Time Enrollment ..................................................................................................................................................31 Academic Standing ....................................................................................................................................................31 Good Standing .............................................................................................................................................................31 Academic Warning .....................................................................................................................................................31 Academic Probation ..................................................................................................................................................31 Academic Recovery Program (ARP) ...................................................................................................................31 Dismissal .........................................................................................................................................................................32 Student Appeals ..........................................................................................................................................................32 Withdrawal From Course .........................................................................................................................................32 Return after a Missed Semester ............................................................................................................................33 Final Examination Policy ..........................................................................................................................................33 Rules of Conduct .........................................................................................................................................................35 Academic Integrity .....................................................................................................................................................35 Attendance ....................................................................................................................................................................35 Institutional sanctions ...............................................................................................................................................35 Classroom Expulsion .................................................................................................................................................35 Electronic Devices ......................................................................................................................................................36 Student Complaints ...................................................................................................................................................36 Honor Code ...................................................................................................................................................................36 Responsibility to Uphold the Honor Code ........................................................................................................36 Honor Pledge.................................................................................................................................................................36 Honor Pledge Reaffirmation....................................................................................................................................36 Academic Honor Council..........................................................................................................................................37 Procedure to Report and Investigate Academic Dishonesty for Minor Violations.............................38 Procedure to Report and Investigate Academic Dishonesty for Major Violations.............................38 During an Academic Dishonesty Investigation..................................................................................................39 Possible Sanctions for Violations...........................................................................................................................39 Suspension from the Institute.................................................................................................................................40 Academic Units and Curriculam.............................................................................................................................41 Academic Environment..............................................................................................................................................41 General Education Requirements..........................................................................................................................41 Electives...........................................................................................................................................................................42 Internship and Field Experience.............................................................................................................................42 Women in Science and Engineering Program...................................................................................................43 Academic Bridge Program.......................................................................................................................................44 Vision................................................................................................................................................................................44 5 Mission.............................................................................................................................................................................44 English Unit....................................................................................................................................................................44 Placement and Exit Requirements........................................................................................................................45 Arts and Sciences Program......................................................................................................................................46 Chemistry Department..............................................................................................................................................46 Communication Department..................................................................................................................................47 Humanities and Social Sciences Department...................................................................................................48 Mathematics Department.........................................................................................................................................48 Physics Department....................................................................................................................................................49 General Studies Department...................................................................................................................................49 Chemical Engineering Program..............................................................................................................................50 Electrical Engineering Program..............................................................................................................................57 Material Science & Engineering...............................................................................................................................63 Mechanical Engineering Program..........................................................................................................................68 Petroleum Engineering Program............................................................................................................................75 Petroleum Geosciences Program...........................................................................................................................82 Course Descriptions....................................................................................................................................................92 Academic Bridge Program Courses......................................................................................................................92 English(ENGL)...............................................................................................................................................................92 Degree Courses.............................................................................................................................................................93 Chemical Engineering (CHEG)................................................................................................................................93 Chemistry (CHEM).....................................................................................................................................................100 Communication (COMM).........................................................................................................................................103 Electrical Engineering (ELEG)...............................................................................................................................103 Engineering (ENGR)...................................................................................................................................................110 Health and Fitness (HFIT).........................................................................................................................................112 Health, Safety and Environment Engineering (HSEG)..................................................................................113 Humanities and Social Sciences (H&SS).............................................................................................................114 Mathematics (MATH)..................................................................................................................................................118 Mechanical Engineering (MEEG)............................................................................................................................121 Materials Science and Engineering (MSEG).....................................................................................................129 Petroleum Engineering (PEEG).............................................................................................................................134 Petroleum Geosciences (PGEG)...........................................................................................................................143 Physics (PHYS)............................................................................................................................................................150 Directory of the Institute..........................................................................................................................................152 Full-Time Faculty.........................................................................................................................................................154 Campus Map.................................................................................................................................................................168 6 Telephone and E-mail Directory Department Admissions Telephone +971 (0)2 6075888 E-mail admissions@pi.ac.ae Academic Bridge Program (ABP) +971 (0)2 6075157 ALLabp@pi.ac.ae Chemical Engineering Program +971 (0)2 60 75276 ALLce@pi.ac.ae Arts and Sciences Program +971 (0)2 6075830 ALLas@pi.ac.ae Electrical Engineering Program +971 (0)2 60 75375 ALLee@pi.ac.ae Graduate Studies +971 (0)2 6075936 ALLgs@pi.ac.ae Housing and Residence Life +971 (0)2 6075499 MALE +971 (0)2 6075832 FEMALE ALLhousing@pi.ac.ae Independent Learning Center +971 (0)2 6075563 MALE (ILC) +971 (0)2 6075895 FEMALE Information Technology +971 (0)260 75793 it@pi.ac.ae Counseling Team +971 (0)2 6075011 counslors@pi.ac.ae Library +971 (0)2 6075802 MALE +971 (0)2 6075879 FEMALE ilc@pi.ac.ae librarian@pi.ac.ae Mechanical Engineering Program +971 (0)2 6075362 ALLme@pi.ac.ae Petroleum Engineering Program +971 (0)2 6075363 ALLpe@pi.ac.ae Petroleum Geosciences Program +971 (0)2 6075271 ALLpg@pi.ac.ae President & Provost Office +971 (0)2 6075713 president@pi.ac.ae Registrar +971 (0)2 6075883 ALLregistrar@pi.ac.ae Student Life +971 (0)2 6075909 ALLsa@pi.ac.ae +971 (0)2 6075157 ALLwise@pi.ac.ae Women in Science and Engineering (WISE) Medical Hotline +971 (0)2 6023265 Security +971 50 6726052 PI Operator +971 (0)2 6075800 Student Support Office Scholarship Office +971 (0)2 6075559 (WISE) +971 (0)2 6075444 (Falcons) wisesos@pi.ac.ae falconsos@pi.ac.ae +971 (0)2 6075819 halmansoori@pi.ac.ae 7 Overview of the Petroleum Institute The Petroleum Institute (PI) was founded by an Emiri decree (Law No. 9 of 2000) on December 30, 2000 under the direction of His Highness Sheikh Khalifa Bin Zayed Al Nahyan. The Institute is financed and governed by a board which consists of members of the Abu Dhabi National Oil Company (ADNOC) and its international partners (BP, Shell, Total and the Japan Oil Development Company). The purpose in founding PI as a university was to provide the UAE, its oil and gas sector and the broader energy industry with engineers educated and trained to the highest standards. The campus is situated in the Sas Al Nakhl area of Abu Dhabi. The teaching and research facilities have up-to-date and modern equipment. The first class of male undergraduate students was admitted in fall 2001 and the first cohort of female undergraduates in fall 2006. The undergraduate programs offered at the PI are: Bachelor of Engineering in Chemical Engineering, Electrical Engineering, Mechanical Engineering, Petroleum Engineering, Metallurgical Science & Engineering, and Polymer Science & Engineering. The Bachelor of Science in Petroleum Geosciences is also offered. All the engineering and science programs are accredited by the Commission for Academic Accreditation (CAA) of the UAE Ministry of Higher Education and Scientific Research. In 2012 five of the undergraduate programs also received accreditation by the Accreditation Board for Engineering and Technology’s (ABET) Engineering Accreditation Commission and the Applied Science Accreditation Commission, specifically, the Bachelor of Engineering in Chemical Engineering, Electrical Engineering, Mechanical Engineering, Petroleum Engineering, and the Bachelor of Science in Petroleum Geosciences. The first batch of male undergraduate engineers graduated in 2005 and the first group of female engineers in 2012. Including the Class of 2012, over 900 engineers and petroleum geoscientists have received bachelor’s degrees and have joined ADNOC and its operating companies. The first graduate programs were established in fall 2007 and include Master of Engineering degrees in Chemical Engineering, Electrical Engineering, Mechanical Engineering and Petroleum Engineering. In 2009, initial accreditation was received for the Master of Science in Chemical Engineering, Mechanical Engineering, Petroleum Engineering and Petroleum Geosciences. Two graduate programs, Master of Science in Applied Chemistry and Master of Engineering in Health, Safety and Environment Engineering, received initial accreditation by the CAA in 2011. The first batch of masters’ student graduated in 2010. In order to encourage academic exchange (including faculty, research scholars, research and graduate students) the Petroleum Institute has signed memoranda of understanding with leading international universities including the University of Texas at Austin (USA), the University of Minnesota (USA), the University of Maryland (College Park, USA), Universiti Teknologi PETRONAS (Malaysia), Tokyo University (Japan), Stanford University (USA), Rice University (USA), the Norwegian University of Science and Technology-NTNU (Norway), Johannes Kepler Universitat Linz (Austria), the Colorado School of Mines (USA) and the China University of Petroleum (China). In addition, the PI is collaborating with the oil, gas and petrochemical industry locally to promote the sponsorship of on-campus research activities and to expand facilities. Finally, our faculty and students are actively engaged in work with the community, whether it is in the form of continuing education courses and workshops or volunteering their time and expertise. The Petroleum Institute strongly supports these activities towards its commitment to the education of students and their development as professionals in the fields of engineering and applied sciences and fulfilling its mission in supporting the advancement of the oil industry in the UAE. 8 Overview of the Petroleum Institute The license of the Petroleum Institute is renewed by the Commission for Academic Accreditation (CAA), Ministry of Higher Education and Research, Abu Dhabi in May 2014. (https://www.caa.ae). The PI received accreditation for five undergraduate programs by ABET (http://www.abet.org)”: the Chemical Engineering, Electrical Engineering, Mechanical Engineering and Petroleum Engineering programs are accredited by the Engineering Accreditation Commission (EAC), and the Petroleum Geosciences is accredited by the Applied Science Accreditation Commission (ASAC). Vision The PI aims to be the preeminent and preferred university in the region, producing internationally recognized graduates and focused research to advance innovative solutions for the energy sector. Mission The PI will provide high quality engineering and science professionals through a continued commitment to excellence in its undergraduate and graduate academic programs alongside fundamental and applied research serving the Oil, Gas and Energy sectors’ need for talent, solutions and advanced technical innovations that contribute to the UAE society and economy. 9 Goals Core Values Excellence and Creativity – We are committed to outstanding performance, innovation and continuous development in all aspects of our mission. Diversity and Tolerance – We recognize the inherent value of a diverse faculty, staff and student body. We respect and treat all individuals with utmost respect and dignity. Inclusiveness and Collegiality – We support an environment that engages our faculty, staff and students and promotes effective participation. We seek and value individuals’ input. Transparency and Fairness – We conduct ourselves and our affairs in an open, transparent and equitable manner. We base our decisions on objective and verifiable information free from personal bias or prejudice. Accountability and Commitment – We fully accept our responsibilities and are committed to achieving them. We take responsibility for our performance in all of our actions and decision. Strategic Goals and Objectives Goal 1 Provide state-of-the-art facilities and employ innovative undergraduate curricula design in accredited programs to attract high quality students and faculty, achieving excellence in engineering and science education and producing outstanding alumni and leaders for the oil, gas and energy sectors. Objective 1.1 Student Excellence – Ensure that PI students’ progress through the curriculum in a timely manner, graduating with the knowledge and skills required of a 21st century engineer and scientist, and meeting the needs of the ADNOC Group of Companies. Objective 1.2 Curricular Innovation and Excellence – Provide foundation and undergraduate engineering and science curricula that follow best practices taking into account requirements of the regional energy sector while meeting international accreditation standards. Objective 1.3 An Optimal Learning Environment – Create an optimal learning environment including state-of-the-art facilities in and out of class. Goal 2 Develop into a dynamic engineering and science graduate school that is highly respected in the region and beyond, with an established reputation for outstanding student accomplishment and excellence in both teaching and research. Objective 2.1 Student Enrollment – Increase full-time graduate student enrollment in existing programs and expand into additional disciplines of relevance to ADNOC Group of Companies. Objective 2.2 Program Quality – Deliver graduate programs of the highest academic quality that adhere to best practice and meet or exceed accreditation requirements. Objective 2.3 Expansion to Ph.D. – Offer programs at the Ph.D. level. Goal 3 Emerge as a leading engineering and science research university focused on the oil, gas, and energy sectors. Objective 3.1 Research Program – Develop a focused research solutions and innovations in collaboration with ADNOC Group align the research portfolio of the PI with the strategic priorities of Companies while accommodating and developing faculty program providing of Companies to of ADNOC Group research interests. Objective 3.2 Research Community and Infrastructure – Attract and develop leading researchers to promote further development of a research culture and ensure that stateof-the-art research facilities are provided with a dedicated research administration. 10 Goal 4 Create a vibrant campus environment for faculty, staff and students to work together offering innovative and enriching learning experiences that foster students’ intellectual and personal development where student success and satisfaction is central priority. Objective 4.1 Student Involvement – Nurture a sense of community, engagement and ownership amongst students. Objective 4.2 Student Development – Provide students with opportunities for meaningful and rewarding personal and professional growth. Objective 4.3 Student Governance – Ensure that the student-related policies and procedures are clear in their intent and consistent in their execution. Goal 5 Foster an intellectual and rewarding environment with fair and equitable policies, procedures and practices that are visible at all levels and enhance performance-driven culture to ensure recruiting and retaining high quality multi-cultural faculty and staff who are committed and satisfied. Objective 5.1 Performance and Promotion – Provide clear, consistent and attainable requirements to achieve performance ratings and promotion. Objective 5.2 Work Environment and Governance – Create a diverse, competitive, fair and collegial work environment where faculty and staff are actively involved in decision-making processes and the implementation of policies and procedures. Objective 5.3 Professional Development – Maintain a supportive work environment that facilitates employees success by providing appropriate training, mentoring and professional development. Goal 6 Stand and be recognized as a pillar of the community through a spirit of sharing and engagement towards strengthening the visibility and outreach activities in the region and globally. Objective 6.1 Visibility – Strive to be recognized as the premier university in engineering and science in the UAE. Objective 6.2 Community Outreach – Utilize the PI’s rich resources in engineering and science to support the UAE’s vision of development and self-reliance. 11 Accreditation and Licensure The Petroleum Institute located in the Emirate of Abu Dhabi, is officially licensed from 01 May 2014 to 30 April 2019 by the Ministry of Higher Education and Scientific Research of the United Arab Emirates to award degrees/qualifications in higher education Campus Facilities Food Outlets Satah, the Student Center is the main dining facility for male students. It serves three meals a day for the PI community. Cafeterias, open for breakfast, lunch and snacks, are located in Habshan, and Zarkuh buildings. A small café is also available in Bu Hasa Building offering breakfast, light lunch and snacks. An ADNOC Oasis convenience store is located in the center of the Men’s Campus. Additionally Arzanah has a large dining facility for female students. It serves two meals a day. There is also a café and ADNOC Oasis convenience store in the building. Other branded outlets will be added in 2015/16 the academic year. Student “Smart” ID cards can be used as a means for payment at main dining facilities. The card can be loaded with Cash at special ATMs in the main canteens. More information on this can be obtained from the Student Office Support (SOS) Center or Residence Life Offices. Housing and Residence Life Vision and Mission Vision The Office of Residential Life will support the mission of PI through a quality program that provides educationally purposeful programming, initiatives and leadership opportunities that promote student growth, independence and persistence at PI. Mission The mission of The Office of Residential Life is to create a safe, supportive, inclusive and engaged living-learning community that enhances students’ personal and academic success. The Office of Residence Life strives to complement the student body’s academic programs of study by constructing and maintaining a student-centered living and learning environment that provides students with opportunities to develop skills to become responsible citizens. Through collaboration with all members of the PI, we promote leadership and personal development by providing opportunities for students to create and implement a vision for their community and future. Resident Life Policy: • Students from Abu Dhabi and its suburb are eligible for the accommodation at the PI • Students from Abu Dhabi city can apply for accommodation upon vacancy availability and the dean’s approval. • Resident life office responsibility is to locate students’ space. The department has the right at redistributing the student according to their level’s or room vacancies and maintenance issue. • The institute has all the authority to withdraw or any disciplinary action upon violations, this will cause of the student losing his privilege i.e... Transportations…..Etc. 12 The Department of Residence Life is committed to: 1. Establishing academic success communities that create and extend student learning opportunities beyond the classroom. 2. Fostering a residential community that values civility, integrity, an appreciation of differences and excellence. 3. Assessing and enhancing services that address the continuously changing needs of the residential environment. 4. Providing a professionally trained customer service oriented staff emphasizing student development theory. 5. Maintaining partnerships with campus colleagues that ensure the quality of residential living Definitions; • • • • • Dormitories: Student housing, referred to as On-Campus Housing. Dorm Coordinator: Residential Life staff member in charge of the dormitory students’ wellbeing; reports to the Dorm Supervisor. Dorm Supervisor: Residential Life staff member who oversees the dormitory students’ wellbeing and oversees the dorm coordinators. Residential Life Office: The office and staff responsible for dormitory operations. Residential Life Program: A comprehensive program that supports healthy and safe dormitory living integrated with diverse activities targeting its residents. Campus Facilities: Facilities at Campus The hostels provide “Meals, Transportation, Housekeeping, Laundry, Clinic, Free Wi-Fi and ADNOC Oasis and Gym Services, and the basic facilities are: Laundry Service PI is providing Laundry Service twice per a week for Male Students and located in B.32-ground Floor. Meals PI provides healthy meals three times a day at a highly subsidized cost for the students. Meals are provided in separate cafeterias for male and female students. ADNOC Medical Clinic Students are entitled to use the on-campus ADNOC Clinic, which provides dental, medical and preventative services. Student Center The student center is a popular place for students to relax after a hard day of studying. Among the facilities available are computer games like X-Box and PlayStation, baby foot, billiards, and snooker. A plasma TV is also available to watch movies and live sport games. Transportation: PI provides transportation to and from the emirate, which belongs according to the student transportation systems and schedule are available Male Students: buses are available from and to every two weeks (twice per month). 13 Resident Life Rules & Regulations; The student declare to commit to the rules and regulations of the PI and aware of the consequences those rules have been violated. Resident students must: • • • • • • • • • • • Take care of their personal properties and be responsible for them. Cooperate with the Resident Life Office to enable him to carry out his duties to achieve the public interest. Provide the Resident Life Coordinators with a photocopy of study schedule at the beginning each semester and present the PI idea upon request. Abide by good conduct with collogues, supervisors, employees and workers in the Housing. Care of cleanliness inside and outside the room and place garbage in allocated areas. Economize in using the facility services such as water and electricity to insure safety and public interest. Inform the Resident Life Office about any defect in electricity, plumbing, etc. Abide by visit times and regulations as stipulated by Resident Life Office. Be quite and abide by the traditions and regulations prevailing in the Housing. Abide by all the rules and regulations of the institute and the trainee affairs department. Vacate the Housing immediately after the completion of the end of term exams, taking into consideration handing over the key to the Security Guard at the reception area of the buildings and taking their personal property. Housing residence students must refrain from: • • • • • • • • • • • Misconduct that does not match a university student conduct whether in his behavior or appearance. Misuse of Housing property, equipment or property of others or moving it from its place without the prior approval of the Resident Life Office. Bringing or keeping any materials, tools, books, or magazines that violates the laws the prevailing traditions and customs. Issue of any releases or statements without the prior approval of the Resident Life Supervisor. Hindering the activity programs authorized in the Housing. Using gas apparatus and misusing the safety tools and fire extinguishers. Bringing personal items to the Housing without the prior approval of the Resident Life Office. Posting any stickers or pictures on the walls or writing or drawing on the walls of any building to the PI. Smoking of all types and methods in the Housing. Behaving or acting in any way that is not of good conduct. Staying in the Housing during the weekend or official holidays except during special cases related to the institute and its programs provided the approval of the student’s guardian is obtained and approval of the Resident Life Supervisor. In case a student violates any of the rules of these regulations pertaining to the Resident Life regulations, the Resident Life Supervisor prepares an initial report of the case to be followed by legal procedures to be taken by student affairs department 14 Dormitory Curfew Campus Curfew and Buildings Closing: The following curfew policy must be followed closely to ensure the safety and well-being of the PI community. Exceptions to the policy must be pre-approved by the Resident Life Department. Campus Gates: Campus Gates will be open at 6:00am and close at 12:00am (midnight). Immediate access will be granted for emergency vehicles (ambulance, fire trucks, police, etc.). No access or deliveries are allowed during closing hours. Male Dormitory Entrances: All exterior doors to dormitory buildings accommodating undergraduate male students will open at 5:00am and close at 1:00am. Immediate access will be granted to emergency personnel only (medical, police, civil defense, etc.). No access or deliveries are allowed during closing hours. Academic Buildings: All exterior doors to academic buildings will open at 7:30am and close at 12:00am. Immediate access will be granted to emergency personnel only (medical, police, civil defense, etc.). No access is allowed during closing hours. Student Support Facilities: Habshan Library, Asab Sports Center, Satah Student Center, and Cafeteria will have individual opening hours posted. Violations: Students must comply with the campus gates and dormitories curfew timings and are expected to abide by the buildings’ rules and regulations. Violators shall receive a warning letter from Resident Life Department. A resident who commits five violations with one semester shall loose the privilege of residing in the dorms permanently. 15 Information Technology Computer Laboratories and Classrooms The IT Department operates and maintains open computer labs in various locations throughout PI campus with a total of four labs (3 in male campus and 1 in female campus). These labs have computers running general office and advanced engineering software and are available for use by students for homework, assignments, projects and other academic activities. The labs have convenient operating hours with IT personnel attending during business hours and provide Internet access, print services, scanning, and more. Additionally, IT maintains departmental computer labs operated by the various academic programs (Ex. Library, physics, Geo Science …) in which Windows and Linux workstations run highly specialized software. Male Campus - - - - Normal Timings Male student labs (weekdays): o Lab 2020: 7:30 – 11:30 o Lab 2028: 7:30 – 11:30 o Lab 4001: 7:30 – 11:30 Male student labs (weekends): o Lab 2028: 7:30 – 11:30 o Lab 2020 “Prior request needed” Female Campus Females student lab (weekdays): o Lab 8375: 7:30 – 5:30 Females student lab (weekends): o No lab available Ramadan Timings Male student labs (weekdays): - Females student lab (weekdays): o Lab 2020 from 7.30 to 3.30 o Lab 8375 from 7.30 to 5.30 o Lab 2028 from 7.30 to 11.30 o Lab 4001 from 7.30 to 3.30 - Females student lab (weekends): o No lab available Male student labs (weekends): o Lab 2028 from 7.30 to 11.30 o Lab 2020 “Prior request needed” Several classrooms are equipped with video conferencing and interactive white board technology. Smart short-throw projectors facilitate better visual presentations and interactive classroom sessions. 3D theater system The PI is proud to have 3D projection system in ADCO Auditorium which is located in Zarkuh building room 1-100. The theater accommodates 180 viewers. To book the auditorium please contact student affairs. Laptop for students The Institute will be launching the laptop for students’ project in the late quarter of 2015. All students going into the arts and science starting Fall 2015. Students will be able to purchase the laptop (Laptop/Tablet Hybrid) from PI. The laptop will come pre-installed with the software suites that the students need for the daily classroom, homework and project activities. The PI will provide technical support for students with their new devices. 16 Multi-Function Printers IT supports nearly 72high-speed, multi-function printers located throughout the campus. These printers provide scan, copy, print services to students and are accessed through PI’s “smart” ID cards. PI Smart Card IT maintains the PI “smart” identification card, which uses RFID technology to facilitate several other services at PI. The card enables library book borrowing, shared Multi-Function Printer (MFP) services, access to dormitories, subsidies for meal / food, and secured access to restricted areas such as labs and classrooms. Several other services will make use of the PI “Smart” ID card in the future. Internet and Wi-Fi Coverage PI enjoys very high speed 1 Gigabit per second connection to the Internet, supported by high speed 10 Gigabit per second LAN backbone connecting our buildings which is one of the highest for an educational entity in the Middle East. Currently, public WI-FI Internet access is available in the student dormitories and most common areas of the major academic buildings. IT Systems Training IT conducts orientation sessions for new students, and training events for students on new technology and on the use of software and learning systems. Available training includes but not limited to Print Management Solution (MFP), CAMS, Blackboard, Meal Voucher System and Help Desk System. Student User Account / Email IT provides each student with a unique username and password to access IT services for the duration of their time at the PI. This includes logging to computer, using email and changing password. This email will be available to you even after you graduate from the PI as part of our services to the institute’s alumni. IT Helpdesk Support The IT Department supports students in campus and in their dormitories. Students can always contact IT helpdesk when they have issues with their user account, email account, ID card, or report any IT problem in a classroom or computer lab. They can use any of the communication channels to contact IT such as helpdesk system, hotline (02/60-75999) or email (helpdesk@pi.ac. ae). File online servers The PI is introducing an online file service for the students of PI that is similar to a drop box experience. Each student will have 3GB of space on the server which delivers high performance and high availability. The students will be able to access the file server anytime and from anywhere via the web on their PC’s or a mobile application. The server offers data protection from viruses, spam, and malware. In addition there is a backup policy that will minimize the loss or corruption of your data. Special Offers The IT Department has enrolled in the Home Use Program, available from Microsoft. As part of this program, The Petroleum Institute’s students can now buy and use Microsoft Office Professional, Microsoft Visio, and Microsoft Project at home for just $9.00 each. ITD is always seeking for the best technology offers to provide you with and below are the latest • • Autodesk Software: This includes AUTOCAD, 3Ds MAX, Softimage, Sketchbook, Inventor, InfraWorks, Maya, Revit, Showcase, MotionBuilder and Design Suite MS Surface Pro: Special discount offer for PI’s end users to purchase the MS Surface Pro 3 17 Library The Petroleum Institute Library is a premier regional information source. It focuses its collection on engineering, energy, and associated engineering and scientific fields. It also maintains select social sciences, humanities, general interest and leisure reading materials. The PI Library strives to be an integral partner in the university’s innovative research, knowledge discovery and scholarly activities. The library’s collection includes more than 110,000 books, oil & gas geological maps, multimedia materials and specialized archival materials. It provides access to these materials both on-site and, to authenticated PI users, off-site anytime via the Internet. The electronic resources index over 300,000 online and print journals. The library catalog provides access to the library holdings. Library users have access to many online research databases and thousands of electronic journals, as well an extensive eBook collection. All e-resources are available via the library portal, accessible both on and off campus. An interlibrary loan service is available for materials beyond the scope of the library collection; this service retrieves items via our regional consortium partners and global commercial document delivery centers. The PI Library enhances and supports the university’s curricular and research programs with innovative services and relevant collections. The PI Library is designed to meet the learning, teaching, research and social development needs of students and faculty. The Petroleum Institute Library includes two campus libraries, serving both the male and female campus communities. The Habshan Library occupies part of the Habshan building ground floor and first floor. The Arzanah Library is located on the first floor of Arzanah Building and supports the Women in Science & Engineering program (WiSE). The library maintains extensive daily operating hours, including evenings and weekends. Each library offers inviting learning spaces, which include an information commons area, quiet reading areas, group study rooms and instruction labs. Both campus libraries offer an environment conducive to both individual study and collaborative work. Both facilities provide wireless access to support learning and research. Librarians provide personalized research support and hands-on instruction in information literacy. The library is a critical resource within the campus and aims to support faculty, students and staff to achieve institutional goals and foster academic success. Sports Complex ASAB is a state-of-the-art Building with dedicated female and male sports facilities. It comprises two gymnasiums, four indoor halls (volleyball, handball, basketball, and badminton), two studios (aerobics and martial arts), two indoor tennis courts, and two squash courts. The Men’s Campus also has a grass soccer field and outdoor basketball court. The Women’s Campus features a gym, an outdoor volleyball and badminton court and a jogging track. Regular intramural sports tournaments are organized, including indoor soccer, basketball, volleyball and table tennis. Student Centers The Student Centers are located in the Satah Building on the Men’s Campus and Arzanah Building on the Women’s Campus. A number of student lounges are also available. These student-centered facilities provide a dedicated setting for social, organizational, and extracurricular activities. The Student Centers are equipped with computers, gaming tables, large flat screen televisions, etc. Women in Science and Engineering Arzanah is a state-of-the-art Building located on the Women’s Campus and home to the Women in Science and Engineering (WISE) Program. It boasts an area of about 14,000 m2, accommodating classrooms and laboratories, administrative and faculty offices, student support and service facilities. The facility includes over 40 classrooms and 50 purpose-built 18 computing, engineering and science laboratories, as well as a library and Independent Learning Center, a workshop, lecture halls and meeting rooms, Tutoring and Writing Center, a 200-seat auditorium, several study and leisure lounges, an exercise room and a dining hall. There is also an outdoor landscaped area with shaded seating. PI Center for Excellence in Learning and Teaching (CELT) The PI Center for Excellence in Learning and Teaching (CELT) is a campus-wide unit focused on enhancing undergraduate science, technology, engineering and mathematics (STEM) education. The mission of CELT is to promote the professional enhancement of PI Faculty by providing formal and informal forums for exchange of experience and expertise in order to enhance STEM instruction. The center organizes seminars and workshops, hosts distinguished international engineering educators, and facilitates a number of Faculty Learning Communities such as Teaching with Technology and Active Learning @ PI. In addition, the center provides funding for course enhancements through its annual CELT Course Enhancement Mini-grant program. Specific services offered are as follows: • Teaching enhancement services • Review of course materials, syllabi and assessments • Classroom visitation/observation services • Promotion of peer observations • Review of student evaluations • Workshop and seminar series focused on best teaching practices • Orientation and support services for new PI faculty • Teacher training for graduate student instructors Health, Safety and Environment (HSE) Vision The Petroleum Institute (PI) shall strive to achieve a safe campus that is in full compliance with all relevant Health, Safety and Environment (HSE) regulations and best practices. The PI will achieve an exemplary HSE performance and will be viewed as a model academic institution that is friendly to the environment and is a safe place to work, learn and conduct research. Policy Every member of the PI community shall adhere to all health, safety, environmental and sustainability policies and procedures that are instituted to protect the health and safety of the PI community, protect and enhance the environment, and propagate a sustainable campus. Commitments The Petroleum Institute shall pursue this policy through: • Conducting HSE-critical activities in a manner designed to minimize HSE risks to a level which is as low as reasonably practicable (ALARP). • Having a systematic and documented approach to HSE management. • Demonstrating visible management commitment and living by the principle that HSE is everyone’s business and that all accidents are preventable and unacceptable. • Operating an HSE incident reporting and facility auditing system and ensuring that followup actions are completed within a reasonable time. • Setting targets for continuous HSE performance improvements and assessment. • Supporting an HSE committee with management, administrative, faculty and student representation to manage all HSE aspects of the work environment. • Providing continuous HSE training to students and employees. • Establishing accountability and a belief that safety is everyone’s responsibility. 19 HSE Expectations • Cooperate during emergency fire drills. When you hear the fire alarm, it is MANDATORY to exit immediately and follow directions to the assembly point area and remain there until you have been given the clearance to return. The PI HSE Department conducts fire drills once each semester in all on-campus buildings. For more details on the fire evacuation procedure and fire marshal duties, please refer to http://pinet.pi.ac.ae/sites/HSEnet/Pages/EmergencyPreparedness.aspx. • Know where the fire alarm activation points are. • Know at least 2 paths of exit to the assembly point. • Observe safety rules in laboratories and workshops. Any accident, near-miss, or first aid case must be reported immediately to the instructor or lab technician and to HSE Department at http://pinet.pi.ac.ae/sites/HSEnet/Pages/IncidentReports.aspx. Each laboratory and workshop has its own appropriate safety protocols that must be followed at all times. • Get your parking permits and drive and park legally on campus. Campus speed limit is 20 km/h. • Aggressive driving, speeding and illegal parking may result in your parking permit being revoked. Entry to and parking on campus requires parking permit decals. Any violation to the PI campus parking rules will result in the revoking of campus parking privileges. • Smoke only in designated areas. Note that the Arzanah Building (both indoors and outdoors) is smoke- free. • Conserve energy and water. Close external building doors if you see them open and turn off lights when not needed. Use water sparingly. • Participate in PI recycling initiatives by disposing recyclables and general garbage in right bins. • Know which number to call in an emergency (within PI: “0” or “75473” or “9-999”). • Report all HSE incidents (first aid cases, accidents, spills, hazards and hazardous conditions). If unsafe conditions, accidents/incidents of any kind, and near–misses are observed, then these should be reported to the instructor or hostel officer and to PI HSE at hse2@pi.ac.ae OR HSE@pi.ac.ae. • Make HSE an equally important job component. Student Success Department The Student Success Department provides tailored support to all students at the PI allowing them to maximize their potential for academic success. Through dedicated advising and counseling, structured tutoring, study groups and workshops, the Student Success Department fosters a learner-centered experience for undergraduate students by empowering students to take an active role in their own success. The Student Success Department provides a supportive, but challenging environment that motivates and inspires PI students. Collaborative exchanges between students, tutors, advisors, counselors and faculty allows students to develop greater self-confidence, independence, and improved academic performance. The Student Success Department houses the two Independent Learning Centers and the Counseling team. Independent Learning Centers (ILCs) The ILCs provide a space for students to come for help in all aspects of their university life. The ILCs house the Communication Writing Centers as well as student help centers for Math, Chemistry, and Physics and Economics, in addition to help centers for each of the 5 engineering programs. These areas are active learning zones where students can seek one-on-one assistance from peer tutors and subject lecturers. The ILCs also host a series of skills workshops that are designed to help students adjust to the rigors of college life. In addition the ILCs also offer an extensive collection of educational films, audio books and audio-based reading enhancement materials. Independent learning multimedia software, DVDs and a multitude of resources are available to provide academic support to PI students. Emphasis is also placed on developing 20 the professional skills of our students and to this end our book collections provide guidance on leadership, entrepreneurship, innovation and engineering ethics. The women’s ILC is located on the second floor of the Arzanah building and the men’s facility ILC is on the second floor of the Bu Hasa Building. Counseling The counseling services are a part of the Student Success department’s commitment to providing supportive services that facilitate the personal growth and development of PI students, and help them make the most of their university experience, both personally and academically. The counselors empower students to make better choices, leading to happier, and more dynamic college life. They provide a trustworthy, confidential and private environment, where students can talk about any academic issues, personal difficulties, social problems and career relatedconcerns. The counseling services offer a solution-focused model of intervention in response to students’ interests and needs. Additionally, support and consultation services are available for staff, faculty and parents who have concerns about the well-being of any PI student. The counselors are also involved in development programs, outreach and retention activities to enhance the educational environment of the PI. The counselors are located within the ILCs. Career Counseling All PI students have guaranteed positions within the ADNOC group of companies upon graduation. With this in mind, the career counseling aims to clarify the academic and career interests of the student and provide assistance in choosing a career path. Health Services The ADNOC Clinic on the PI campus provides primary health care to PI students, faculty, and staff members and their dependents. The Clinic is open Sunday – Thursday 7:00 a.m. to 11:00 p.m. and provides 24-hour accident and emergency care as well. Depending on the nature of the illness, patients may be referred to the main ADNOC Clinic or other hospitals or clinics for further treatment. A dedicated clinic for female students is available in Arzanah and is open Sunday – Friday 7:30 a.m. to 5:00 p.m. Students desiring to use the PI Clinics must present a valid health insurance card. Students may also be provided health insurance by their sponsor. Mail Service The PI provides mail service on campus. Mail is distributed daily to all Institute offices by staff from the Facilities, Maintenance and Services Department (FMS). The Mail Room handles all outgoing mail including courier services and is located on the ground floor of the Habshan Building on the Men’s Campus. A second mail room is located in Arzanah on the Women’s Campus. All mail intended for Institute offices and for those residing on campus should be addressed to: The Petroleum Institute, P. O. Box 2533, Abu Dhabi, U.A.E. Public Relations The Public Relations Office ensures a good working relationship between the Institute and the local public and private sectors. 21 Student Records A permanent record reflecting the academic achievements of each student who enrolls at the PI is maintained by the Registrar’s Office. Comprehensive student records contain information related to admission, transfer credit assessment, registration, disciplinary actions, academic assessment, progress towards degree, grade point average, and graduation. Privacy Rights of Students Students have the right to: • Inspect and review information contained in their educational records; • Request changes or updates to their personal data; • Consent to disclosure, with the extent of UAE federal and local laws, of personally identifiable information from education records. Transcripts and Other Records All transcripts and documents submitted from other institutions become the property of the Petroleum Institute, and, as such, come under control of the Registrar’s Office. The PI will not provide copies of these documents. Transcripts submitted to the PI for review of transfer credit also become the property of the PI and cannot be returned to the student or forwarded to other institutions. Release of Transcripts and Student Information Students may obtain official transcripts of their academic records at the PI from the Registrar’s Office. Transcripts will only be released after receipt of prescribed fees (AED 20/copy) and a signed Request for Transcript of Record Form from the student concerned endorsed by the Student Sponsor. The PI will issue only complete transcripts, not parts of a student record. Information in a student’s file or about a student may be released to another party only with the written consent of the student or in order to comply with the order of a court or any other body with the authority to require the release of such information. The Registrar’s Office provides students with official letters that might be required by various government and/or private organizations. 22 Admissions The Petroleum Institute is highly selective, granting admission only to applicants who have demonstrated in their academic performance in secondary or post-secondary school that they are able to do the classroom and laboratory work required, and are motivated to complete and profit from the programs offered. Criteria considered in evaluating students include (1) courses taken in secondary or post-secondary school or college, (2) grades earned in those courses, and (3) English language proficiency. The requirements set out below are the minimum for admission and are subject to change. The Governing Board reserves the right to deviate from published admission requirements. In such cases, changes in policy will be widely publicized. Admission to the Petroleum Institute is primarily reserved for UAE Nationals; however, highly qualified non-nationals may apply and are admitted on a case-by-case basis. Admission Process Advertisements are published in the local press and on the PI web site stating the specific requirements for admission and inviting applications from suitably qualified individuals. In order to be considered, an applicant must submit all the required forms and meet the minimum requirements. On admission, the student will be notified, instructed to take a physical examination and required to report to the Petroleum Institute for orientation prior to the start of classes. Admission Requirements Admission requirements are set to address minimum criteria for UAE National applicants and Non – UAE Nationals. Admission requirements are reviewed annually and published on the PI website and in the student catalogue. For UAE Nationals graduating from the Public High schools, the minimum requirements are a minimum average of 75% overall and an average score of 75% in Math, Physics and Chemistry. For Non-UAE Nationals graduating from the Public High schools, the minimum requirements are a minimum average of 95% and an individual score of 90% in each of the following subjects: Math, Physics and Chemistry. Minimum requirements for applicants graduating from other school curricula (for example American or British systems) are listed on the PI website. Applicants must satisfy the English language entry requirement when applicable. The minimum English proficiency required for Non-UAE National applicants is a minimum score of TOEFL iBT 79 or Academic IELTS 6.5. The minimum English proficiency required for UAE National applicants is a minimum score of TOEFL iBT 61 or Academic IELTS 6.0. As of 30 August 2015, the PI no longer accepts TOEFL PBT scores. UAE Nationals who do not obtain the English language proficiency score at the time of admission may be placed into one of three levels of Academic Bridge Program (ABP) English courses based on their CEPA score or an internal PI placement test. English language proficiency exams must be conducted at approved testing centers. Exams taken from any other center will not be considered. The list of approved centers is reviewed periodically. The current list is published on the PI website. The original score certificates should be sent to PI directly from the testing centers. Applicants are required to pass the medical exam and a Good Conduct Check prior to enrollment. Admission decisions shall only be considered final upon receiving approval from the ADNOC Selection Committee; successfully completing the medical exam, obtaining the Good Conduct Check; and signing the ‘ADNOC Contract of Study’. 23 Contract of Study Applicants who received approval from the ADNOC Selection Committee and successfully completed the medical exam and the Good Conduct Check are invited to sign the ‘ADNOC Contract of Study’ at the Petroleum Institute campus with their guardians. After signing the contract, students are expected to abide by the policies and regulations of ADNOC and the Petroleum Institute. Deferral New students may defer their admission for a maximum of two regular semesters by submitting a completed ‘Temporary-Permanent Withdrawal Form’ to the Student Support Offices at Habshan (for male students) and Arzanah (for female students) buildings during the ‘Add/Drop’ period. They have to submit a ‘Request to Resume Studies Form’ to the Registrar’s Office after their deferred semester/s to be re-admitted to the Petroleum Institute. Appeals for re-admission are subject to the consideration of the Student Appeals Committee and the approval of the Petroleum Institute President. Students who are unable to commence their studies after two deferred semesters have to reapply during the admission period published on the PI website. Transfer Students Students seeking admission to the Institute on transfer status must apply a semester prior to the semester for which they are seeking admission. All applicants who are interested in transferring to the Petroleum Institute should first meet the minimum requirements. In addition, all UAE national transfer candidates should possess a minimum of 2.50 GPA (Grade Point Average) in their current university with a minimum score for TOEFL iBT 61 or Academic IELTS 6.0 (only from approved testing centers). Non-UAE nationals should possess a minimum of 3.00 GPA (Grade Point Average) in their current university with a minimum score for TOEFL iBT 79 or Academic IELTS 6.5 (only from approved testing centers). Transfer credit may be awarded for previously completed college or university courses if the original grade earned was not lower than a C (or its equivalent). If the content of the completed courses correspond to the content of a degree course offered at the PI, then up to 50% of the credit hours can be transferred to any undergraduate degree program. Transfer students should provide their official transcripts at the time of admission. In order to be eligible for transfer to the Petroleum Institute, the following conditions apply: • • • • • 24 Upon admission, the student should complete a ‘Transfer Credit Evaluation/Approval Form’ and submit it to the Registrar’s Office The Registrar’s Office will inform the applicant of the course(s) transferred for credit and possible equivalencies. A minimum of 50 percent of the academic credit applied toward graduation must have been earned from courses taken at the Petroleum Institute. Original documents must be in English or accompanied by an official certified English translation. In order to evaluate a student’s file for possible transfer of credit: • • • • • • • Documents must include the official transcript, academic catalog course description and course syllabi. A student’s evaluation for possible transfer of a course will be administered only once. Transfer files will be evaluated, and students will be awarded possible credit, by the first day of add/ drop of the student’s first semester at the Petroleum Institute. Students will be notified of the results of their course evaluations by the Registrar’s Office. The decision regarding the awarding of credit is made in the appropriate academic program. The Registrar’s Office maintains and updates the transfer student files. The awarding of transfer and non-traditional credit is governed by the provisions below: Courses, with a minimum grade of “C” and deemed equivalent in content and level to those offered at the Petroleum Institute, will be transferred as equivalent PI courses. Other appropriate courses, with a minimum grade of “C”, may be transferred as free/open electives or unassigned courses in the relevant area. Courses completed more than four years prior to matriculating as an undergraduate student at the Petroleum Institute are not transferable. Furthermore, at the time of graduation, no course can be more than six years old if it is to be counted toward the awarding of an undergraduate degree. Credit is not granted twice for substantially the same course taken at two different institutions. Studying at Another Institution Enrolled PI students wishing to take a course for credit with another higher education institution as a visiting student may be allowed to do so with permission from the Program Chair. The student must complete the appropriate request form, attach the course description and syllabus of the course in which he/she is intending to enroll and submit it to the appropriate Program. Upon Program approval, the form is submitted to the Registrar’s Office. The process for awarding the credit is the same as other transfer credit. Credit Awarded through Non-Traditional Sources Credit awarded through non-traditional sources must meet the minimum established grade, score or level as follows: • The minimum grades, scores, and levels for evaluating high school credit, such as AP, GCE, A-Levels, IB Higher Levels, etc., are established, documented and regularly reviewed by the relevant Arts and Sciences Program department in conjunction with the Registrar’s Office. • A student’s eligibility to sit a challenge exam is established by the appropriate program. • Credit awarded through other non-traditional sources, such as documented life experience, will be reviewed by the appropriate program on a case-by-case basis. Any resulting recommendation for academic credit must be approved by the Provost (or designee). • Transferred courses and non-traditional credit will be recorded on the student academic transcript with the appropriate number of credit hours. A grade of “TR” will be assigned and is not included in the calculation of the student’s CGPA. Placement Tests Before students can enroll in classes at the Petroleum Institute, they must take the internal PI placement tests. Department chairs and academic advisors will use the placement test results to help students enroll at appropriate course levels. The majority of new students will be placed in the Academic Bridge Program (ABP). This program is designed to help students make the transition from their secondary school courses to the rigorous academic programs at the Petroleum Institute - all of which are taught in English. 25 Readmitted Students A former student who wishes to re-enroll and seek re-admission must complete a ‘Request to Resume Studies’ Form available from the Registrar’s Office. When approved, the form should be submitted to the Registrar’s Office. Former students who were suspended or dismissed should refer to the section on “Return after a Missed Semester, Full Withdrawal from a Semester, Suspension or Dismissal.” Non-Degree Students A non-degree student is a student who does not wish to pursue a degree program at the Petroleum Institute but wishes to take courses for other purposes. Examples could be visiting students from other universities, taking courses to qualify for admission to a graduate program or professional development. Such students may take any course for which they have the pre - requisites or have the permission of the instructor. Official transcripts or officially certified copies of transcripts or other evidence of the pre- requisites is required. An applicant for admission as a degree student who does not meet admission requirements may not fulfill deficiencies through this means. Nondegree students who subsequently become degree students at the PI may receive credit for a maximum of 12 credit hours for courses completed as a non-degree student. Declaration of a Major Students admitted to the PI are free to declare the degree program in which they intend to major at the time of entry into the Academic Bridge Program. There are no significant differences in the requirements of the Freshman year for the current degree programs. However, to avoid unnecessary delays in graduation, all students should decide on their major by the end of the first semester of the Freshman year. Students wishing to change their major must complete a “Change of Major” Form and submit to the Registrar’s Office. Once processed within the Academic Management System (CAMS), the student’s “Catalog of Record” will automatically be updated. Also refer to “Catalog of Record”. The seven undergraduate majors currently offered at the Petroleum Institute are Chemical Engineering, Electrical Engineering, Mechanical Engineering, Metallurgical Engineering Petroleum Engineering, Petroleum Geosciences, and Polymer Engineering. 26 Grades and Grade Point Averages Grades are an important component of the learning assessment process. All courses must be assigned a grade in the middle and end of the semester or session in which the course is offered. It is the responsibility of the course instructor to inform each class at the beginning of the semester or session of the nature of the course assessment and corresponding grades assigned. Each course instructor should include a grading metric in the course syllabus. When a student registers in a course, one of the following grades will appear on his/her academic record. The assignment of the grade symbol is based on the level of performance. It represents the extent of the student’s demonstrated mastery of the material listed in the course syllabus and achievement of the stated course objectives. A = 4.00 Excellent A-= 3.75 B+= 3.25 B = 3.00 Good B-= 2.75 C+= 2.25 C = 2.00 Satisfactory C-= 1.75 D = 1.00 Unsatisfactory F = 0.00 Failure XF= 0.00 Failure due to Academic Dishonesty W = Withdrawn WA= 0.00 Withdrawn Administratively WF= 0.00 Withdrawn failing (late Withdrawal) WI= Withdrawn Involuntarily (Terminated) TR= Transfer Credit CR= Credit (Passing) NC= No Credit I = Incomplete Z = Grade not Submitted “A,” and “A-“ are honor grades. They are awarded as a mark of outstanding performance and for achievement clearly of a higher order than average. They indicate that the student has demonstrated not only the ability to work successfully, but also the ability to do some creative thinking or problem solving in the field. They will not be given for routine performance of the assigned work in the course. “B+,” “B,” and “B-“ indicate very good performance, definitely above a satisfactory level, but not as good in analytical thinking and originality as that required for grades of “A” or “A-.” Thorough competence to do very good work in the field is required for these grades and they will not be given for mere compliance with the standards set for successful completion of the course. “C+,” “C,” and “C-“ are the grades given for range of satisfactory performance. They indicate compliance with the standards set for successful completion of a course. “D” is recorded to show that the student’s performance is marginal and it does not represent satisfactory progress toward a degree. “F” indicates failure and entirely unsatisfactory performance. It carries the requirement that to obtain credit, the entire course must be repeated. “XF” is a penalty grade. It indicates that a student has failed due to academic dishonesty. “W” indicates that a student has withdrawn from a course. The grade does not calculate in the student’s grade point average. “WA” indicates administrative withdrawal. The grade does not calculate in the student’s grade point average. 27 “WF” indicates administrative withdrawal and failure of a course. It calculates as an “F.” “WI” indicates administrative withdrawal from all registered courses in that particular semester. It calculates as an “F.” “TR” is a substitute grade awarded to all transfer or non-traditional credit courses. “CR” indicates satisfactory performance. The grade does not calculate in the student’s grade point average. “NC” indicates unsatisfactory performance. The grade does not calculate in the student’s grade point average. “I” indicates that the student has not yet completed the course requirement. The grade doesn’t calculate in the student’s grade point average. It is considered as an incomplete grade and is given when the student is absent from several sessions of, or the final exam of a course because of illness or other reasons considered beyond the student’s control. Approval by the Provost (or designee) must be secured by the instructor before a grade of “I” may be assigned. When the work missed is satisfactorily completed, the final grade must be approved by the Program Chair of the course being offered and subsequently forwarded to the Registrar’s Office. A student must complete the requirements for the course in which the “I” grade was received by the last day of add/drop period of the next regular semester or the grade will automatically be changed to a grade of “F.” If any extension is required, then the deadline will be the end of the next regular semester. All such special requests must be approved by the Provost (or designee). If a grade of an “I” has been given, the instructor must file the specific forms for a final grade signed by the Program Chair with the Registrar’s Office once the missed work is satisfactorily completed. “Z” is awarded to show that no grade was submitted by the instructor. Grade Appeal The grades earned by a student are determined by the instructor of the course and can be changed only upon the instructor’s recommendation, endorsement of the Program Chair and final approval by the Provost (or designee). In case of an official grade appeal, a student must submit a “Grade Appeal” Form to the Registrar’s Office no later than the first day of classes of the next regular semester. The Registrar’s Office will review and forward the form to the Student Appeals Committee. The committee will make a recommendation to the Provost no later than the last day of add/drop. If any extension is required, then the deadline will be the end of the semester. Under the following exceptional circumstances, a grade may be changed by someone other than the instructor of the course: • As set forth above, the Provost must approve a grade of “I” and the Program Chair must approve the final grade once the work missed is satisfactorily completed. • The Provost may, only upon recommendation of the Student Appeals Committee, change a grade determined to be awarded in an unfair manner or not in the best interest of the Institute. “C-“, “D” and “F” Repeat Provision Except for special courses (i.e., Special Topics, Research Topics, Independent Study Courses, etc.), a student may repeat a course only one time. A written appeal must be submitted to the Provost should a student need to repeat a course more than once. A student may only repeat courses with an earned grade of “C-“, “D” or “F”. Undergraduate students are allowed grade point average recalculation in up to five repeated courses. Only the first five repeated courses will be eligible for recalculation. Only the highest grade earned in the repeated courses counts towards the cumulative grade-point average. Additionally, only the course with the highest grade will count towards the cumulative credit earned. The grades for all attempts of a course taken for credit appear on the student’s official transcript. The repeated course must be taken at the PI as transfer courses are not included in 28 this policy. A student should meet with his/her advisor and appropriate PI departments before repeating a course, as it may affect the student’s academic standing, scholarship, PI six year rule, etc. A repeated course must be taken when it is regularly offered and cannot be taken in independent or individual format. Any questions regarding this policy should be addressed to the Registrar’s Office Grade-Point Averages In calculating a student’s grade point average, all assigned letter grades “A” through “F” will be utilized. The grade point average is calculated on all work for which the student has registered with the exception of the courses with grades of “W”, “WA”, “WF”,“WI”, “TR”, “CR”, “I”, “NC” and “Z” and courses repeated (see Repeat Provision). The grade point average is the ratio of the number of quality points gained to the number of credit hours attempted. Grade point averages are calculated to two places following the decimal point. Quality Hours and Quality Points In order to graduate a student must successfully complete a certain number of required credit hours and must maintain grades at a satisfactory level. The system for expressing the quality of a student’s work is based on quality hours and quality points. For example, the grade “A” represents four quality points, “B” three, “C” two, “D” one, “F” and “XF” none. The number of quality points earned in any course is the number of credit hours assigned to that course multiplied by the numerical value of the grade received. The quality hours earned are the number of credit hours in which grades of “A” through “F” are awarded. To compute a grade- point average, the number of cumulative quality points is divided by the cumulative quality hours earned. Grades of “W”, “WI”, “TR”, “CR”, “I”, “NC”, “PR” or “Z” are not counted in determining quality hours. Transfer Credit Excluded in GPA Calculation Transfer credit earned at another institution will be recorded on the student’s permanent record. Calculation of the grade point averages for transfer students will be based only on grades earned in degree courses completed at the Petroleum Institute. Credit Hours The number of times a class meets during a week (for lecture or laboratory) usually determines the number of credit hours assigned to that course. For a small number of courses additional hours of instruction have been added to the lecture part of the course in order to improve students’ understanding of the material. As a result, some courses with four or five lecture contact hours will carry only three or four credit hours for the lecture portion of the course. Lecture sessions are normally 50 minutes long and typically represent one hour of credit for each 50 minutes the class meets in a week. Two to four hours of laboratory work per week are typically equivalent to one hour of credit. In order to make satisfactory progress towards graduation in 4 years, undergraduate students should enroll in 15 – 19 credit hours each semester. Students wishing to enroll in 19 or more credit hours in a given semester must obtain written approval from the Provost (or designee). Students on Academic Probation cannot take more than 13 credit hours in a fall or spring semester. On average, each hour of lecture requires at least two hours of preparation outside of class. Honor List A degree-seeking student will be placed on the semester Honor List if he/she satisfies the following requirements for a particular semester: • The student has entered a degree program; • The student has earned at least 15 hours in that semester; • The student has a semester GPA of 3.50 or higher; and • The student has no grades of incomplete (I) for that semester. 29 Graduation Requirements Catalog of Record For the purpose of academic standing and verification that all graduation requirements have been met, the Catalog of Record is either that of the academic year the student entered the Major or the academic year the student graduates. Under certain circumstances, a course substitution may be allowed. If approved, the “Course Substitution” Form is submitted to the Registrar’s Office in order to update the student’s degree audit in Academic Management System (CAMS). All substitutions must be approved by the student’s degree program and the Provost (or designee). The Petroleum Institute reserves the right to make changes in academic regulations, policies and offerings as circumstances may require. Time Limit on Study A student must satisfy all graduation requirements within six years of the first enrollment at the Petroleum Institute as a degree student. Graduation Requirements Students must successfully meet the following to complete the requirements for a bachelor’s degree: Complete all coursework in degree program sequence as published in the student’s academic catalog of record within six years of first enrollment at the Petroleum Institute as a degree student; Under certain circumstances, a course substitution may be allowed. If approved, the “Course Substitution” Form is submitted to the Office of the Registrar in order to update the student’s degree audit in Student Information System. All substitutions must be approved by the student’s degree program and the Provost (or designee). The Petroleum Institute reserves the right to make changes in academic regulations, policies and offerings as circumstances may require. Have a minimum cumulative grade point average of 2.00 for all academic work completed in residence (excluding pre-matriculation courses); A minimum of 50 percent of the academic credit applied toward graduation must be earned from courses taken at the Petroleum Institute (See PIP 3200 Transfer and Non-Traditional Credit); Have a minimum cumulative grade point average of 2.00 for all courses either having the subject code of the candidate’s major program or being used to satisfy technical elective requirements in the program; Have a minimum of 30 credit hours in 300 and 400 level courses at the Petroleum Institute with at least 15 credits taken with Senior standing. A minimum of 15 credits must be earned in the student’s major courses; The certification by the Registrar that all required academic work is satisfactorily completed; Recommendation by the faculty and approval of the Governing Board. This policy pertains only to the grade point average required for graduation and does not pertain to the grade point average calculated for special academic recognition, graduation honors, admissions requirements for particular programs, or any other academic related standards. This policy pertains only to the grade point average required for graduation and does not pertain to the grade point average calculated for special academic recognition, graduation honors, admissions requirements for particular programs,or any other academic related standards. Academic Rules and Regulations Academic Bridge Program (ABP) Student Student who has not yet met English language proficiency requirement Degree Student enrolled in degree courses Freshman 0-29 earned credit hours Sophomore 30 - 59 earned credit hours Junior 60 - 89 earned credit hours 30 Senior >90 earned credit hours Non-Degree Student enrolled in a degree course but not proceeding towards a degree Full Time Enrollment Students are required to register for at least 12 credits (12 credits is defined as full-time) each fall and spring semester unless they receive special permission from the Provost (or designee). Full time registration in fall and spring semesters is necessary to maintain progress toward graduation. In order to ensure timely graduation, please follow to the appropriate program of study listed in the catalog. For the summer session, students are allowed to register for a maximum of two courses. Only one of the two courses may carry a lab component. Students registered for an Internship are not allowed to register for any additional courses. Academic Standing At the end of each regular semester, a degree student’s academic standing is assessed based on the accumulated total quality hours, cumulative grade point average (CGPA), and the semester grade point average (SGPA). A minimum semester (SGPA) and cumulative (CGPA) grade point average to maintain satisfactory progress toward graduation is detailed below: Good Standing Maintain a CGPA and SGPA of at least 2.0 with 12 earned semester credit hours unless fewer credit hours are approved by Provost (or designee). Academic Warning Any semester, in which a student’s SGPA or CGPA falls below 2.0 or the student fails to complete 12 credit hours (unless fewer credit hours are approved by Provost or designee), the student will be placed on “Academic Warning”. A student on “Academic Warning” returns to “Good Standing” by completing 12 or more credit hours in a regular semester and achieving a minimum Semester GPA of 2.0 and a Cumulative GPA of 2.0 Academic Probation If during the next semester of enrollment after receiving “Academic Warning” a student’s SGPA or CGPA is below 2.0 or he/she fails to complete at least 12 credit hours (unless fewer credit hours are approved by Provost or designee), the student is placed on “Academic Probation”. Such a student must consult with an academic advisor and may register for no more than 13 credit hours for the next semester of enrollment or 4 credit hours in a summer session. A student placed on academic probation will not be allowed to add or drop courses, or register, without the approval of his/her academic advisor. “Academic Probation” will appear on the student’s permanent academic record. The Office of the Registrar will notify the student, guardian, and sponsor of the student’s probation status. The notice will include a requirement for the student to meet with his/her academic advisor no later than the drop/add period. At the end of any semester in which a student is on Academic Probation their subsequent academic standing will be determined by three conditions. Where all three conditions are met then the student shall return to good standing. Where only two conditions are met then the student shall continue on probation. Where one or no condition is met then the student shall be placed into the ARP. The conditions are: 1. SGPA is 2.0 or greater; 2. CGPA is 2.0 or greater; 3. Successful completion of at least 12 credit hours in the relevant semester. Academic Recovery Program (ARP) In addition to the stipulations above, students who fail both MATH 060 and CHEM 060 in the same semester will be placed in the ARP. While enrolled in the ARP the student should register for a maximum of 9 Credit Hours (unless more credit hours are approved by the Provost or designee) at the PI, repeating courses with F,D, C- or NC grades, or may register for a maximum 31 of 4 Credit Hours in a Summer Session repeating a course with F, D, C- or NC grades with no drop/withdraw allowed. A student enrolled in the ARP shall adhere to the academic plan devised by the Academic Advisor. A student may be placed only once in the ARP for a maximum duration of one regular semester during their academic career at the PI. Only courses taken at the PI shall be eligible to satisfy ARP requirements. At the end of the ARP semester if the student has achieved a minimum of C grade in all registered courses s/he shall return to Probation. Academic Dismissal A student may be dismissed where s/he: 4. Fails either MATH 060 or CHEM 060 twice. 5. Fails to fulfil the conditions required to exit the ARP; or 6. Is on probation after exiting the ARP and fails to fulfil the requirements to return to good standing or continued probation Exclusion of Sanctions in Summer Sessions In order to afford students the opportunity to improve their academic progress during Summer Sessions, the usual academic standing procedures will not apply. A student’s academic standing will be updated only in the following cases: 7. If the student was on Academic Warning and achieves a minimum of 2.0 CGPA and a minimum of 2.0 SGPA in a Summer Session; the academic standing will be updated to Good Standing. 8. If the student was in the ARP and achieves a minimum of C grades in the registered course in Summer Session; the academic standing will be updated to Academic Probation. 9. If the Student Appeals Committee reviews a student appeal in regard to academic and financial issues and makes its recommendations to the Provost (or designee.) Student Appeals Committee (SAC) Students who feel that a rule or regulation was applied unfairly may submit an appeal in writing. Appeals will be considered by the Student Appeals Committee. The committee considers both academic and financial appeal cases. The appeal should be accompanied by relevant evidence, such as a letter from a medical doctor or other official documentation. When considering an appeal, the Student Appeals Committee may take into consideration the student’s total academic record, attendance record or any other information on file which will assist them in reaching a fair decision. Probation may not be appealed. The Student Appeals Committee consists of five members drawn from the teaching and student life staff. Members, appointed by the Provost beginning of each academic year, serve for one year. A member is eligible to serve for more than one term. A minimum of three members is sufficient to consider any appeal. Decisions of the Student Appeals Committee are final. After reviewing the cases, the SAC make its recommendations to the Provost (or designee). The following details the appeals process. • Appeals must be submitted in writing to the Registrar’s Office. The deadline for submitting an Academic Appeal is the first day of classes in the following semester. • The Student Appeals Committee will review all appeals no later than a week following the submission deadlines. All recommendations are forwarded to the Provost for approval no later than one week from the date the appeal was submitted. • Results of the appeal will be given to the student in writing by the Registrar’s Office, and a copy of the final decision will be placed in the student’s file. Decisions of the Student Appeals Committee are final. Withdrawal from Studies A student may discontinue his/her studies in part or full for a specified period of time. The following scenarios and conditions apply: Add/Drop: Students may add, drop or change a course section at the beginning of a regular semester or session during the official add/drop period. Courses dropped during the official add/ 32 drop period will not appear on a student’s official transcript. Withdrawal from a Course after the Official Add/Drop Period: Students may withdraw from any degree course during the official withdrawal period. A grade of “W” will be assigned on the student’s transcript. Students withdrawing from any course should discuss the decision with their instructor, academic advisor, and with a student counselor. Students should be aware that withdrawal from a course may have an impact on their scholarship terms and timely progress toward graduation. All student requests for withdrawal from a course must be processed by submitting a completed “Course Add/Drop/Withdrawal” form to the Office of the Registrar by the stipulated deadline. Withdrawal for a Semester: Students may drop from all degree courses during the official add/ drop period without any record of enrollment in the courses appearing on their transcripts. Students may also withdraw from all degree courses during the official withdrawal period. In such cases a grade of “W” will be assigned on the student’s transcript. Students should be aware that withdrawing for a semester will have an impact on their scholarship terms and timely progress toward graduation. All student requests for withdrawing for a semester must be made by submitting a completed “Temporary/Permanent Withdrawal Request” form to the scholarship department and will only be processed after all obligations to the PI have been fulfilled. Withdrawal from the PI: All requests for permanent withdrawal from the Petroleum Institute must be made by submitting a completed “Temporary/Permanent Withdrawal Request” form. Students may not withdraw after the official withdrawal period and will be assigned the grade earned. Return after a Missed Semester, Full Withdrawal from A Semester, or Dismissal A student who has withdrawn for a semester does not have an automatic right to return to the Petroleum Institute. All requests to re-enroll after a missed regular semester of study must be made by submitting a completed “Request to Resume Studies” form to the Office of the Registrar. Approval to return does not guarantee required courses will be offered during the semester or session of return. Approval to return does not guarantee a seat in required courses in any semester or session. Returning students must satisfy any academic conditions put in place by the Student Appeals Committee or be permanently dismissed from the PI without further appeal. In the case of students resuming studies after a period of suspension due to honor code violations or other misconduct the PI will not accept transfer credit earned during or after the suspension or dismissal period to be counted towards their undergraduate degree. All other PI policies and procedures apply. Final Examination Policy • A final examination shall be held at the end of undergraduate courses according to the examination schedule published by the Registrar’s Office. In order to reduce scheduling conflicts, final examinations are scheduled in accordance with a pre-established template by the Registrar’s Office. There should be at least one study-day prior to the first day of final examinations. • The last day of final examination period is designated as Make-Up Examination Day. Students with scheduling conflicts or with permission for rescheduling a final examination may sit the examination on this day. • Final examinations cannot be rescheduled or cancelled except by the Office of the Registrar. Final examinations cannot be scheduled during regular class days. • If a student is scheduled for more than two final examinations on one day, then he/she must notify the Registrar’s Office within five days from the publication of the Final examination Schedule to make the necessary adjustment to his/her schedule. • A student who is absent from a final examination without a valid excuse will normally receive a “zero” for that examination. If a valid excuse is accepted by the instructor, the policies on incompletes or change of grade will apply. In addition to the final examinations, one or more major examinations may be planned for a course. The examination schedule shall be included in the course syllabus. Such examinations shall not be scheduled during the last week of classes. The course instructor is responsible for notifying students in writing of any changes in these examination schedules prior to the 33 scheduled examination. A student who is absent from a major examination without a valid excuse will normally receive a “zero” for the examination. For provisions governing valid excuses see PIP 3150 Student Attendance. During examinations all students shall: Be prepared to show current PI ID; Follow all instruction given by the proctor(s); Arrive on time for the examination or they may be denied access. However, in no case shall a student who is 30 or more minutes late for the examination be admitted nor shall the scheduled duration of the examination be extended; Not be permitted to leave during the first 30 minutes or last 10 minutes of the examination; Leave all unauthorized materials (textbooks, notes, electronic devices, bags, etc.) at the front of the examination room. All unauthorized electronic devices taken into the exam room must be turned off; Conform to seating arrangements as established by the proctor(s); Cease to talk once seated in the examination room and for the duration of the examination; Leave the examination paper/book face down until the proctor announces the beginning of the examination; Keep the examination paper/book flat on the desk at all times; Keep the examination paper/book stapled or bound. Students failing to follow the above general rules may be requested by the proctor(s) to leave the examination room. Their examination paper/book may be confiscated and a “zero” assigned for the examination. All cases of suspected cheating are governed by PIP 3175 Honor Code. The Office of the Registrar shall publish the above general rules in conjunction with the final examination schedule. 34 Rules of Conduct Academic Integrity The PI is an academic community whose purpose is the pursuit of knowledge and the development of its graduates as leading experts in their academic disciplines. In light of this purpose, it is essential that all members of this community are committed to the principles of truth and academic honesty. To maintain the highest level of academic integrity, this policy defines the standards to which the PI expects its students to adhere. Attendance Regular class attendance is an important component of the learning process. Students are required to attend classes regularly. All faculty members are required to maintain accurate and up-to-date records of student attendance using the Student Information System (CAMS). Students absent from class shall be subject to the following policy. Excused absences: Official approval from Student Affairs is the only means of excusing a student’s absence. The following provisions apply: • It is the student’s responsibility to apply for an absence to be excused. Once the application is approved, Student Affairs shall inform the instructor. • Medical certificates, personal correspondence and other documentation may not be accepted by instructors as excusing a student’s absence. Instead, these should be provided to Student Affairs who are the final arbiter of what documentation is required in order to process a student’s application for their absence to be excused. • The decision by Student Affairs to grant or decline a student’s application to excuse his/her absence is final and no appeal shall be permitted. • When possible, students should seek prior approval for an excused absence. • Examples of excused absences, refer to PIP3150 Section 6.4.5 Instructor-imposed sanctions: Instructors may impose penalties for unexcused absences subject to the following provisions • A student may be absent for no more than SEVEN percent (7%) of contact time from a course in which s/he is currently enrolled with no penalty, provided that the student’s absence does not result in him/her missing any items of assessment (quizzes, exams, turning in homework etc.). • For unexcused absences beyond 7% of contact time, the instructor may impose a penalty not exceeding a total of 5% of the student’s final grade, calculated in accordance with the attendance policy specified in the course syllabus. Institutional sanctions The following shall apply when a student has been absent for more than 25% of contact time from a course in which s/he is currently enrolled (including excused absences). If the 25% limit is reached on or before the last day to withdraw from classes, as specified in the academic calendar, then the Student Information System (CAMS) will automatically assign a letter grade of WA (Withdrawn Administratively). In all other cases a letter grade of WF (Withdrawn After Deadline) will be assigned. Classroom Expulsion In order to maintain a positive learning environment, rude, disruptive, and inconsiderate behavior by students in class will not be tolerated. Students are required to be present and ready to begin class promptly on the hour, and should plan other activities and transit time between classes accordingly. Students who are chronically late to class or disruptive in other ways are subject to removal from class following one warning by the instructor. Any work missed because of a student’s removal from class cannot be made up and will be assigned a score of zero. Students who repeatedly disrupt the class are subject to permanent removal from the course following consultation with the Provost (or designee). 35 Electronic Devices Electronic devices including mobile phones must be turned off when entering the PI academic facilities. They are not to be used during class. Student Complaints The PI is committed to providing fair and equitable treatment for all students. In the event that a student develops concerns regarding his/her treatment at the PI, they are encouraged to contact to the Dean of Student Life where they will be referred to a student counselor for assistance. The student counselor will recommend appropriate steps to deal with the issue. Some complaints are best handled with the student counselor acting as an advocate for the student and attempting to resolve the matter with the appropriate person or body. On other occasions, students may be advised to talk with a given faculty member or a program chair. Some issues where there is no immediate resolution may require the student to implement a formal appeals process. Honor Code The Petroleum Institute is an academic community whose purpose is the pursuit of knowledge and the development of its graduates as leading experts in their academic disciplines. In light of this purpose, it is essential that all members of this community are committed to the principles of truth and academic honesty. To maintain the highest level of academic integrity, this policy defines the standards to which the Institute expects its students to adhere. Responsibility to Uphold the Honor Code It is the responsibility of all members of this academic community – students, faculty, and staff alike – to actively deter and report all instances of academic dishonesty in order to safeguard the academic standards of the Institute. Honor Pledge The Honor Pledge is a short statement attesting that each student will fully comply with the Petroleum Institute’s Honor Code. The Honor Code is published in Arabic and English. It is the students’ responsibility to familiarize themselves with the Institute’s Honor Code and adhere to it. Every student admitted to the Petroleum Institute will sign the Honor Pledge and receive a copy of the Honor Code upon signing their contract in the Admission Office. The Honor Pledge is as follows: “I verify that I have received a copy of the Petroleum Institute’s Honor Code and hereby pledge to fully comply with the Code.” _________________________ Student Signature 36 Honor Pledge Reaffirmation The Honor Pledge Reaffirmation is a short statement attesting that each assignment, exercise, examination, project, presentation, report, etc. is the student’s own work. It is a reminder to the students that the Institute is committed to academic integrity. The faculty is expected to enforce the use of the pledge. The Honor Pledge Reaffirmation should be typed or handwritten and signed on all graded work submitted in the form of a hard copy; is should be included on electronically submitted work as well, where its inclusion will count as a signature. The Honor Pledge Reaffirmation is as follows: “I pledge that I have neither given nor received any unauthorized assistance whatsoever on this academic assignment, exercise, examination, project, presentation, report, etc.”. _________________________ Student Signature 37 Academic Honor Council • The Academic Honor Council (AHC) is appointed by the Provost with no special limits on the length of service. • The AHC will consist of six (6) members with the chair being appointed by the Provost: • Three (3) faculty members including at least one female (voting) • One (1) staff member (voting) • The Student Council President or designee - female/male (voting) • Director of Student Life or designee (non-voting) • The AHC will be charged with maintaining the highest level of academic integrity at the Institute, and deliberating cases of suspected academic violations. Procedure to Report and Investigate Academic Dishonesty for Minor Violations • If an instructor suspects that a student has committed a minor violation, s/he should meet with the student to discuss the allegation. The meeting must take place within three (3) working days from when the alleged violation took place. • If the instructor determines that no academic violation has occurred, the matter is dropped. • If the instructor determines that a minor violation has occurred, s/he shall: • Apply a sanction, if any, in accordance with the “Possible Sanctions for Violations” terms listed below. • Notify the student and the instructor’s Program Chair/Department Head and submit a report through the student information system detailing the violation and sanction applied (if any) within five (5) working days from when the meeting with the student(s) took place. • Submit a report to the Student Life Office, with a copy to the Program Chair. • The third minor violation documented with the Student Life Office will be referred to the AHC. Procedure to Report and Investigate Academic Dishonesty for Major Violations • If an instructor suspects that a student has committed a major violation, s/he should meet with the student to discuss the allegation. The meeting must take place within three (3) working days from when the alleged violation took place. • If the instructor determines that no academic violation has occurred, the matter is dropped. • If the instructor determines that a major violation has occurred, s/he shall notify the student and the instructor’s Program Chair/Department Head and submit a report through the student information system detailing the violation within five (5) working days from when the meeting with the student(s) took place. • The student’s file will be automatically referred by the student information system to the Judicial Officer (or designee) who will review the case, gather the evidence and present it, in writing, to the AHC. The AHC: Upon receiving the case: • Will hold a meeting with the Judicial Officer (or designee) and, if necessary, the student and/or instructor for the purpose of examining the evidence and questioning any witnesses or relevant parties. • Based on the evidence, if the AHC decides that the student has committed an academic violation, • they will determine an appropriate sanction. The AHC may recommend any sanction in accordance with item 6.5 of this document. The AHC is required to submit a full report, including the recommended sanction, to the Provost 38 (or designee) for a final decision. Such decision will be communicated to the Office of the Registrar. Where the Provost (or designee) determines to impose a sanction other than that recommended by the AHC, written justification shall be provided to the AHC. The Office of the Registrar will communicate the final decision to the student and instructor. During an Academic Dishonesty Investigation • A student under investigation for an allegation of an academic violation may not withdraw from the course in question. • A student may not graduate as long as any allegation of an academic violation remains unresolved. • Unavailability of any of the concerned parties will not hinder the continuation of the investigation. • Students may seek advice about the Academic Integrity Policy and its procedures from the Student Life Office. Possible Sanctions for Violations Guidelines for sanctions to be applied based on the severity of the violation. • Requirement to attend scheduled developmental workshops on relevant topics: Opportunistic cheating in assignments, exercises, examinations, projects, presentations, reports, etc. that have a limited effect on a student’s course grade. • Reduced grade or 0 for the work: Opportunistic cheating in assignments, exercises, examinations, projects, presentations, reports, etc. that have a limited effect on a student’s course grade. • Reduction in course grade by one letter grade: Premeditated cheating in assignments, exercises, examinations, projects, presentations, reports, etc. that have a limited effect on a student’s course grade. • XF or reduction in grade for the course: Opportunistic cheating in assignments, exercises, examinations, projects, presentations, reports, etc. that have a significant effect on a student’s course grade. • Suspension for one semester and an XF for the course: Premeditated cheating in assignments, exercises, examinations, projects, presentations, reports, etc. that have a significant effect on a student’s course grade. • Expulsion from PI: Premeditated cheating in assignments, exercises, examinations, projects, • presentations, reports, etc. that have a significant effect on a student’s course grade. 39 Suspension from the Institute A student found guilty of academic dishonesty may be suspended for one or more semesters. The AHC will determine the length of suspension. Once imposed, the AHC will recommend the effective date for suspension, which could be immediate. If suspended during an academic semester, the student will receive a grade of XF (Failure due to Academic Dishonesty) for the concerned course and a WI (Involuntary Withdrawal-Terminated) for all remaining courses. The Institute will report the case to the student’s guardian and sponsor. A student may appeal an XF grade recorded two years earlier in accordance with the appeals process stated in this policy. Appeals If a student wishes to appeal the instructor’s or AHC’s decisions, s/he must comply with the following: • All appeals must be in writing and provide new information not considered previously. • All appeals regarding minor violations must be submitted to the Judicial Officer (or designee) within ten (10) working days from the decision date of the instructor. The Judicial Officer (or designee) shall • forward the case to the AHC to review, deliberate and decide. The AHC’s decision is final. • Appeals regarding major violations must be submitted to the Judicial Officer (or designee) within ten (10) working days from the decision date of the Provost. The Provost will review, deliberate as needed, and decide on the case. The Provost’s decision is final. • Appeals may result in the application of a lesser, identical or more severe sanction. Record of Sanctions • All records of sanction for all cases will be kept in the Student Life Office. • A record of any sanction requiring action by the Registrar’s Office will be placed in the student’s file at the Registrar’s Office. • In cases of major violation the Institute will provide a record of the sanction upon request from the student’s guardian and sponsor. 40 Academic Units and Curricula Academic Environment The academic environment at the Petroleum Institute is exciting because of the interaction of students with experienced professors and instructors, many of whom have worked in the petroleum industry, and because students are learning in state-of-the-art facilities. Students also meet other students who will become lifelong professional colleagues. The academic environment is challenging, as expected at a first-class engineering institution, and different from that which most UAE students have experienced in secondary schools. The majority of classes are conducted in English, and most students start with the ABP (Academic Bridge Program) which is a rigorous one-year program designed to enable students to develop the study skills, work habits and attitudes students need in order to succeed in undergraduate Engineering studies. English language skills are developed to meet PI requirements. The ABP Department will also help students in developing the necessary integrity and personal and interpersonal skills to become successful students and engineers. Students in the engineering programs learn the fundamentals of engineering and science in large part by solving practical engineering problems and in petroleum-related projects, working either individually or in groups. Subjects are interrelated and students integrate knowledge gained in one course with that gained in others. Students average 5 or more contact hours a day with faculty in the classroom and are expected to devote 3-4 hours each day including weekends on homework. Grades are based on examinations, periodic in- class tests, homework, individual and group projects, laboratory exercises, class participation, and attendance. Refer to the syllabus for specific course requirements. General Education Requirements The General Education courses are designed to provide students with the basic knowledge in chemistry, mathematics and physics. It is also intended to broaden the curriculum by exposing students to topics in communication, humanities and social sciences. The goal is to better understand the many non- technical disciplines and develop an appreciation of economic factors, history, aesthetics, ethics, and societal and global impact of engineering practice. Along with their discipline study, the general education component helps students develop essential leadership and communication skills, improve writing and computer literacy skills, and enhance their ability to work in teams and think critically. The Petroleum Institute requires undergraduate students to complete the following courses in general education requirements for a total of 54 credits: CHEM 101 General Chemistry I COMM 101 Communication I COMM 151 Communication II ENGR 102 Introduction to Engineering HFIT 111 Personal Health and Fitness I H&SS 111 Islamic Studies H&SS 350 Economics H&SS XXX Humanities and Social Sciences Elective I H&SS XXX Humanities and Social Sciences Elective II MATH 111 Calculus I MATH 161 Calculus II MATH 212 Calculus III PHYS 191 Physics I – Mechanics PHYS 241 Physics II – Electromagnetism and Optics STPS 201 Strategies for Team-Based Engineering Problem Solving I STPS 251 Strategies for Team-Based Engineering Problem Solving II 41 Electives Each degree program requires its students to complete at least 3 credits in a major elective course and/ or technical elective course. A major elective course is an elective course offered through the program of study. A technical elective course is an elective course offered outside the program of study. For a complete listing of the major elective courses and technical elective courses, and the total number of electives required, refer to the individual program of study in this document. Internship and Field Experience A summer practical training program is required for undergraduate students major in Chemical, Electrical, Mechanical and Petroleum Engineering at the Petroleum Institute. The prime objective of the Summer Internship Program is to provide our undergraduate engineering students with hands-on exposure to oil and gas industry facilities, thereby furthering their understanding of the basics and operations of sciences and its applications in the oil and gas industry. During the assignment period, students apart from technical exposure, will also learn to work in teams that possess diverse knowledge and skills; experience project management; develop time management; and most importantly learn to understand rules and regulations as well as adhere to policies and procedures. Students’ communication and presentation skills are expected to improve after the internship period as a result of constant contacts with mentors and administrative personnel. Students must make the best use of this opportunity to apply their theoretical background in engineering learned at the PI to solve design and maintenance problems and demonstrate an awareness of current and future engineering applications in the oil industry. This Program take place once a year in the summer only for a total duration of eight weeks exactly; Interns start registering for this course from early spring semester of each academic year. Students, once assigned, must agree to spend eight weeks with the assigned organization on-site and/or in offices except for off-shore sites where the respective company’s policy prevails.The pre-requisites to take the courses are : • Student must have a minimum cumulative GPA of 2.0 • Student must have a minimum of 90 earned Credit Hours by the start of the internship program. The internship program is mainly successful due to the unlimited support received from Abu Dhabi National Oil Company Scholarship Department, ADNOC Group of Companies (AGCs), ADNOC’s industrial partners and reputed international organizations committed to contributing to the development of United Arab Emirates. The internship Office coordinates the internship placement of PI Students with interested industrial partner, faculty advisors, and process all related requirements for the internship placement. Students are placed under the direct supervision of a mentor in the ADNOC group of companies, or with one of the international stakeholders.The intern is given a significant individual engineering project in a discipline-specific environment. The nature of the work assignment is tailored to the student’s intellectual development level, and involves actual engineering project work including, where possible, collection and synthesis of data, analysis, and reporting. The intern also has a PI faculty advisor, who is required to interface with the student and the mentor periodically to assess progress and respond to questions. A Final report is required at the completion of the internship; this report becomes part of the student’s permanent record at the PI and is used as input into the Program’s assessment process. A formal evaluation of the student is carried out by both the faculty advisor and the company mentor at the conclusion of the internship; this information is also be used as part of the Academic Assessment Program. For Junior Petroleum Geosciences students, a mandatory Field Work Program is required in Italy and Spain for a total of 30 days. 42 Women in Science and Engineering Program The mission of the Women in Science and Engineering (WISE) Program is to promote women’s education attainment, professional aspirations, social responsibility and personal growth. The Program aspires to develop successful female engineers and scientists who will make meaningful contributions to the profession and society at large. The Program was founded in Fall 2006 and aims to: • • • • Inspire lifelong learning. Foster leadership skills. Encourage civic involvement. Promote engagement in applied sciences and engineering. To meet these goals, a correlated set of objectives has been established to ensure proper planning and effective implementation. Objectives include: • Providing opportunities that aim at academic involvement, research activity and continuous learning. • Encouraging participation in extra-curricular activities that emphasize a balanced learning experience, leadership and collaborative work. • Exposing students to role models and inspiring individuals who promote women’s active involvement in the workforce and society at large. • Advocating involvement in community-related activities and outreach programs. • Promoting sustainable practices and ethical conduct in all actions. • Engaging in professional activities that highlight women’s contributions in the fields of applied • sciences and engineering. For further information on the specific degree requirements, please refer to the individual degree program sections of this catalog. 43 Academic Bridge Program Vision The vision of the Petroleum Institute ABP Department is to develop and maintain a leading center of academic excellence in the preparation of students for undergraduate studies in Engineering and Applied Sciences. Mission The mission of the Academic Bridge Program is to provide students with the necessary knowledge, skills and proficiency in English consistent with success in engineering and science studies. Academic Bridge Program Student Learning Outcomes (SLO) The ABP program-level outcomes are tabulated below to show Knowledge, Skills and Aspects of Competency as follows: SLO An ABP student will, by the end of the program, meet the requirements for successful transfer into the Arts & Sciences program and will possess: 1 the communication skills appropriate for undergraduate study. 2 an ability to work individually and in teams. 3 an awareness of, and ability to engage in, independent study and life-long learning. 4 an ability to utilize information and communication technology. 5 an ability to think critically and creatively. 6 an awareness of the norms and practices of an academic culture and of the wider society. The mission of the ABP is to provide learners with opportunities to achieve sufficient proficiency in academic English to succeed in their undergraduate studies. Because of the PI’s emphasis on measurable achievements, the ABP English curriculum has an outcomes-based framework. After completing the ABP English curriculum, students will have sufficient English skills to be able to: • listen to short and long conversations/lectures and extract general and detailed information; • speak clearly in class presentations and answer questions from an audience; • read critically to extract general facts and specific details, stated or inferred, from academic texts; and • produce a variety of texts using notes, reference material and background knowledge/ experience. ABP facilities include fully-equipped language classrooms and computer laboratories. Classrooms are equipped with data projectors, smart boards (in Arzanah Building), white boards, bulletin boards, computers, and overhead projectors. ABP students are assessed on a regular basis. There are periodic quizzes and writing tests as part of students’ continuous assessment. 44 Placement and Exit Requirements 1. Placement: Newly admitted students will be placed into their ABP courses based on their scores on one of three tests- the CEPA exam, the IELTS or the TOEFL iBT. ABPS 010: English 1 Students whose entry CEPA score is below 171 or equivalent will enter the English 1 course. In this course, students study English for 24 hours per week. This is to prepare for English 2 and 3 levels. English 1 lasts for one semester. ABPS 020: English 2 Students whose entry CEPA score is between 171 and 177 (or IELTS 5.0/TOEFL iBT 36-47) will be placed in English 2. Students receive 20 hours per week of English and academic skills. English 2 lasts for one semester. ABPS 030: English 3 Students whose entry CEPA 178+ (or IELTS 5.5/TOEFL iBT 48-60), or who have satisfied the requirements of English 2 progress to English 3. Students receive 20 hours per week of English and academic skills. Students will improve their English and academic skills sufficiently to exit ABP and begin studies in the Arts & Sciences Program. English 3 lasts for one semester. 2. Exit Requirements: Students must achieve an a minimum IELTS 6 or TOEFL iBT score of 61 to meet the Ministry of Higher Education and Scientific Research requirements for entry into the College of Arts & Sciences. 45 Arts and Sciences Program The Arts and Sciences Program consists of the following departments: Chemistry, Communication, General Studies, Humanities and Social Sciences, Mathematics, and Physics. The mission of Arts & Sciences is to provide undergraduate students with a high quality education which broadens and supports their intellectual and practical development through academic excellence, scholarly activity and provision of the knowledge, skills and dispositions necessary to succeed in a globalized world. Arts & Sciences Program Student Learning Outcomes • Outcome 1: An ability to apply knowledge of the basic sciences (math, chemistry and physics) to identify, formulate, analyze, and solve problems. • Outcome 2: An ability to design and conduct experiments, and analyze and interpret resulting experimental data. • Outcome 3: An ability to develop and use appropriate data gathering instruments to undertake research. • Outcome 4: Understanding of a variety of political, social, cultural, economic and ethical points of view with reference to contemporary global and regional issues. • Outcome 5: An ability to use techniques, skills, and modern engineering design tools. • Outcome 6: An understanding of the engineering design process as a means of obtaining conceptual solutions to engineering problems. • Outcome 7: An ability to function effectively in teams. • Outcome 8: An ability to communicate effectively, in English, in spoken, written, and graphical formats. • Outcome 9: An awareness of, and engagement in, independent study and life-long learning. Chemistry Department The mission of the Chemistry Department is to provide students with the fundamental knowledge and skills in chemistry that they will require for their engineering and sciences studies and subsequent careers. Its vision is to provide a focal point for chemistry, both in terms of teaching and research, within the PI and in the wider UAE community. The Chemistry Department goals are to: • • • • Establish a clearly defined role for chemistry within the Petroleum Institute. Enhance excellence in undergraduate teaching across campus. Promote research in chemistry. Enhance faculty and staff development. The Chemistry Department has a number of state-of-the-art instructional laboratories including: • General Chemistry laboratories with preparation and storage rooms (5) • Organic Chemistry laboratories (3) with gas chromatographs, gas chromatograph-mass spectrometers, Fourier Transform Infrared spectrometers, and one 60 MHz NMR • A research laboratory with access to an ICP-MS instrument; an HPLC-ICP-MS facility; and an • HPLC instrument. • Access to a 400 MHz NMR spectrometer in the Chemical Engineering Program 46 The Chemistry Department contributes to courses for the general education requirements of the PI, as well as compulsory courses and technical electives for some of the majors. Courses offered include: CHEM CHEM CHEM CHEM CHEM CHEM 060 Introduction to Chemical Principles 101 General Chemistry I 102 General Chemistry II CHEM 211 Organic Chemistry I CHEM 212 Organic Chemistry II 301 Physical Chemistry 293/393/493 Special Topics in Chemistry CHEM 394/494 Research Topics in Chemistry 396/496 Independent Study in Chemistry Communication Department Mission The mission of the Communication Department is to develop Petroleum Institute students’ application and understanding of English communication and professional practice, enabling them to participate effectively in their studies and in their eventual workplaces. Values The work of the Communication Department is predicated on the belief that students’ communication and professional skills are most effectively developed through student-centered and team-based approaches that necessitate collaboration in the acquisition and articulation of knowledge. Instructors primarily facilitate learning and team processes, using feedback embedded in a review process to guide students, and introducing the concepts and skills of academic integrity, reflection, collaboration, metacognition and critical thinking through which students enhance their learning strategies, their participation in a team, their self-reliance, and the oral and written outcomes of their own and their team’s efforts. Goals The department’s goals are to guide students to develop the knowledge, skills and competencies necessary to achieve the following learning outcomes: • Demonstrate ability to develop and use data gathering instrument(s) in research, and analyze and discuss results (COMM SLO2). • Demonstrate an ability to work effectively in a team (COMM SLO6). • Demonstrate effective communication (COMM SLO7). • Demonstrate engagement in independent study and the development of lifelong learning skills • (COMM SLO8). Communication Department courses include: • COMM 101 COMMUNICATION I • COMM 151 COMMUNICATION II 47 Humanities and Social Sciences Department H&SS furthers life-long learning by promoting an awareness and understanding of human behavior expressed in students’ histories, political and economic systems, faiths, oral and written languages and leadership behaviors in a manner that prepares them for further academic study, professional excellence and contributive citizenship. H&SS produces innovative research in scholarly and professional media that contributes to an advanced understanding of specific topics within the sphere of H&SS. Its vision is to be a regionally recognized center of teaching and research excellence in the humanities and social sciences. The Humanities and Social Sciences Department contributes to courses for the general education requirements of the PI. Courses offered include: H&SS 111 Islamic Studies H&SS 112 Arabic Language H&SS 121 German Language I H&SS 171 German Language II H&SS200 Introduction to Business Management H&SS 201 The West in the Middle East H&SS 221 Introduction to Political Science H&SS 222 The UAE Before and Since the Discovery of Oil H&SS 251 Principles of Economics H&SS253 Topics in Quranic & Hadith Studies H&SS261 Engineering Ethics from an Islamic Perspective H&SS 321 The Political Economy of Japan H&SS 333 The History and Politics of Middle East Oil H&SS 374 Islamic Banking and Finance H&SS 293/393/493 Special Topics in Humanities and Social Sciences H&SS 394/494 Research Topics in Humanities and Social Sciences H&SS 396/496 Independent Study in Humanities and Social Sciences Mathematics Department The mission of the Mathematics Department is to serve the PI community through excellence in teaching, research and scholarly activities. Its vision is to be recognized for its contributions in teaching and research both at the national and international levels. The Mathematics Department contributes to courses for the general education requirements of the PI and technical electives for some of the majors. Courses offered include: MATH 060 College Mathematics MATH 111 Calculus I MATH 161 Calculus II MATH 212 Calculus III MATH 241 Probability and Statistics MATH 261 Differential Equations MATH 361 Advanced Engineering Mathematics MATH 365 Numerical Methods MATH 371 Operations Research for Engineers MATH 461 Linear Algebra MATH 293/393/493 Special Topics in Mathematics MATH 394/494 Research Topics in Mathematics MATH 396/496 Independent Study in Mathematics 48 Physics Department The mission of the Physics Department is to teach physics courses in innovative ways that will help PI students meet all the requirements for graduation and thereby contribute to their preparation for successful careers as engineers. Its vision is to be recognized within the PI and the wider community as a center for innovative teaching and excellence in research. The Physics Department has a number of state-of-the-art instructional laboratories including: • Takreer Physics Studios: modern student-centered learning environments for PHYS 191 (2) Electromagnetism and Optics Laboratories (2) • Mechanics and Waves Laboratories (2) • Modern Physics that allows student experiments such as Franck-Hertz experiment, Moseley’s law and determination of the Rydberg constant using X-rays, determination of Planck’s constant, Compton effect, conductivity in solids, etc. and technical electives for some of the majors. Courses offered include: PHYS 060 Introductory to University Physics PHYS 191 Physics I – Mechanics PHYS 241 Physics II – Electromagnetism and Optics PHYS 341 Modern Physics with Applications PHYS 293/393/493 Special Topics in Physics PHYS 394/494 Research Topics in Physics PHYS 396/496 Independent Study in Physics General Studies Department The mission of the General Studies Department is to assist in preparing engineering students to meet the challenges of their profession by providing hands-on learning in areas of team based engineering problem solving and design communication. The General Studies Department is committed to academic excellence, and fostering an interactive learning environment that would motivate students to successfully engage in engineering education. The General Studies Department has a number of state-of-the-art computer laboratories with the latest computer aided design software. The General Studies Department contributes to courses for the general education requirements of the PI. Courses offered include: ENGR101 Introduction to Engineering in the Petroleum Industry STPS201 Strategies for Teambased Engineering Problem Solving I STPS251 Strategies for Team-based Engineering Problem Solving II 49 Chemical Engineering Program Bachelor of Science in Chemical Engineering Mission and Description The mission of the Chemical Engineering Program at the Petroleum Institute is to provide a world class education in chemical engineering to produce engineers and future leaders who are capable of meeting or exceeding the needs and expectations of ADNOC, and other allied sponsors. The field of chemical engineering deals with the science and engineering of chemical reactions and separation processes. Accordingly, the degree program begins with basic studies in chemistry, including organic and physical chemistry, and the thermodynamic properties of fluids. The program continues with courses in basic chemical engineering calculations and advanced courses in fluid mechanics, heat and mass transfer. Reactor design, petroleum refining, gas processing, process control, computer-aided process design, and engineering economics are important components of the program. Students’ access to state- of-the-art laboratories including unit operations, reaction engineering, thermofluids, and control systems as well as pilot-plant settings are deemed vital in the program. Educational Objectives Within the first few years after graduation, the career and professional accomplishments of the Chemical Engineering Program graduates are: • Successful practice of the chemical engineering profession. • Design and safe operation of process plants including the oil, gas and petrochemical industries. • Satisfactory career growth fulfilling ADNOC’s competency targets. • Successful career in research and development. Program Outcomes Upon completion of the Chemical Engineering Program at the Petroleum Institute, our graduates will be able to: • apply knowledge of basic sciences (mathematics, chemistry, and physics) and engineering; • design and conduct experiments, as well as analyze and interpret data; • carry out safe and economic design of chemical engineering processes and systems fulfilling environmental and societal constraints; • function effectively in inter- and intra-disciplinary teams; • apply knowledge of chemical engineering fundamentals to the identification, formulation, analysis and solution of chemical engineering problems; • demonstrate professional integrity and ethical responsibility; • communicate effectively in English, both oral and written; • exhibit an understanding of the impact of engineering solutions in a global, economic, environmental, and societal context; • inculcate a passion for life-long learning and self-education; • demonstrate an awareness and understanding of contemporary environmental and social issues in the regional and global context; and • use the computational and process simulation tools necessary for chemical engineering practice. 50 Program Facilities The Chemical Engineering Program laboratories are located in the Arzanah and Ruwais Buildings. These include: • • • • • • • • • Catalysis Laboratory Computing Laboratory Instrumentation Laboratory Polymer Chemistry Laboratory Polymer Processing Laboratory Polymer Properties and Characterization Laboratory Reaction Engineering Laboratory Thermodynamics Laboratory Unit Operations Laboratory Professional Chapters and Clubs The Chemical Engineering Program supported the founding of the American Institute of Chemical Engineering (AIChE) Student Chapter in spring 2009. The aim of the chapter is to promote chemical engineering and establish a bridge between PI students and the professional community at large. AIChE holds regular meetings for its members and organizes social and technical activities open to all students. Degree Requirements The Chemical Engineering Program at the Petroleum Institute is designed to give students a rigorous education in the fundamentals of chemical engineering science, and specific training in applications of chemical engineering in the oil and gas industries. The program incorporates extensive laboratory work and computer process simulation in order to reinforce the principles and concepts used in the classroom. The program features a summer internship in industry where students will gain significant exposure to the petroleum processing industries in the Middle East or elsewhere in the world. The Chemical Engineering Program requires 132 credits to graduate distributed as follows: 52 credits in General Education Requirements, 71 credits in Major Requirements, and 9 credits in Electives of which at least 6 credits in Major Electives. 51 Program of Study for Chemical Engineering Term Fall Course Code Credit CHEM 101 General Chemistry I 4 COMM 101 MATH 111 ENGR 101 HFIT 111 Communication I Calculus I Introduction to Engineering in the Petroleum Industry Personal Health and Fitness TOTAL General Chemistry II Communication II Calculus II Physics I - Mechanics TOTAL 4 4 3 1 16 4 4 4 4 16 Sophomore Year Organic Chemistry I 4 CHEM 102 COMM 151 Spring MATH 161 PHYS 191 CHEM 211 CHEM 212 MATH 261 CHEG 232 Spring CHEG 212 STPS 201 Organic Chemistry II Differential Equations Fluid Mechanics Computational Methods in Chemical Engineering Strategies for Team-Based Engineering Problem Solving I TOTAL 3 4 4 3 18 4 3 3 3 3 16 Summer CHEG 397 Chemical Engineering Internship 3 Fall 52 Course Title Freshman Year MATH 212 PHYS 241 CHEG 205 H&SS 251 Calculus III Physics II – Electromagnetism and Optics Principles of Chemical Engineering Principles of Economics TOTAL Term Course Code Course Title Credit Junior Year Fall CHEM 331 Physical Chemistry 3 CHEG313 CHEG335 STPS251 H&SS111 Experimental Design and Analysis Heat Transfer Strategies for Team-Based Engineering Problem Solving 3 3 Islamic Studies TOTAL CHEG 332 CHEG 324 Spring CHEG 314 Chemical Engineering Thermodynamics Mass Transfer Engineering Economics 3 3 15 3 3 3 CHEG354 Chemical Engineering Laboratory I 3 H&SS XXX Humanities and Social Sciences Elective II 3 TECH XXX Technical Elective 1 TOTAL 3 17 Senior Year Fall CHEG 423 CHEG 443 CHEG 490 CHEG 455 CHEG XXX CHEG 491 CHEG424 CHEG 412 Spring H&SS XXX CHEG XXX Gas Processing Engineering Reaction Engineering Chemical Engineering Design Project I Chemical Engineering Laboratory II Major Elective I TOTAL Chemical Engineering Design Project II Petroleum Refining and Processing Process Dynamics and Control Humanities and Social Sciences Elective II Major Elective II TOTAL Total Credit Hours 3 4 3 2 3 15 3 3 4 3 3 16 132 53 List of Electives Major Electives (at least 6 credits) CHEG 325 Fundamentals of Nanotechnology CHEG380 CHEG 381 CHEG 415 CHEG 416 CHEG 440 CHEG 470 CHEG 472 CHEG 488 CHEG293/393/493 CHEG 394/494 CHEG 396/496 Introduction to Polymer Science and Engineering Polymer Chemistry and Reaction Engineering Combustion and Air Pollution Control Corrosion Engineering Separation Processes Industrial Catalysis Water Treatment and Membrane Processes Polymer Properties Special Topics in Chemical Engineering Research Topics in Chemical Engineering Independent Study in Chemical Engineering 3 3 3 3 3 3 3 3 3 1-4 1-4 1-6 Technical Electives (up to 3 credits) HSEG 401 Introduction to HSE Engineering 3 HSEG 405 MATH 361 MATH 461 MEEG 334 MEEG 454 MEEG 459 MEEG 479 MEEG 480 PEEG 342 PHYS 341 System Safety Engineering Advanced Engineering Mathematics Linear Algebra Materials Science Refrigeration/air conditioning and cryogenics Turbo Machinery Engineering Project Management Renewable Energy Technologies Production Facilities Modern Physics 3 3 3 3 3 3 3 3 3 3 • Courses from outside the list require approval from the Chemical Engineering Department Chair (or designee). • For a list of H&SS Elective courses, refer to the Arts and Sciences Program section of this document 54 55 56 Electrical Engineering Program Bachelor of Science in Electrical Engineering Mission and Description The mission of the Electrical Engineering Program is to provide a world-class education in electrical engineering with emphasis on power and control systems, and instrumentation engineering that prepares graduates for successful professional careers in ADNOC, other allied sponsors, and the broader energy industry. In addition, graduates will engage in life-long learning that will enable them to continue their education throughout their career. The Electrical Engineering Program at the Petroleum Institute is designed to give students a sound education that covers the major subjects of electrical engineering and draws applications from the oil and gas industries. In their senior year, the electrical engineering students take a variety of courses in power engineering, which comprises power generation, transmission, and distribution systems, and in instrumentation and control, which involves instrumentation and measurements, modern control, computer control techniques, real-time programming, and industrial automation. The electrical engineering curriculum combines strength in electrical engineering fundamentals with extensive laboratory experience to reinforce the principles and concepts used in classroom, design experiences to apply learned knowledge to solve representatives of real-world problems and an environment that stresses leadership and teamwork. In addition, the curriculum emphasizes the development of computer and oral and written communication skills of electrical engineering students. The Electrical Engineering laboratories are equipped with state-of-the-art instrumentation components, development systems tools for teaching and research. Educational Objectives Consistent with the institutional vision and mission and those of the Electrical Engineering Program, with input from program constituencies, the faculty has adopted a number of educational objectives. The overall goal is to provide students with an outstanding learning environment and the necessary education so they will have the tools and resources to compete successfully in the global workplace or to pursue advanced studies. The program will strive to use novel technologies and methodologies for teaching. Within the first few years of graduation, the career and professional accomplishments of our Electrical Engineering Program graduates will be to: • Communicate effectively in English and function well on teams; • Demonstrate understanding of and practice professional attitudes and ethics within a global and societal context; and engage in lifelong learning. • Succeed in pursuing a career or graduate studies in electrical engineering using appropriate theoretical and experimental, problem-solving, and design skills. • Design new or improve power and/or control systems. • Develop solutions to engineering problems utilizing diverse knowledge from a variety of sources. • Function well and succeed in the future work environment with ADNOC Group and corporate sponsors through attainment of sponsors’ competency targets. 57 Educational Objectives On completion of the Electrical Engineering Program, graduates will be able to: • Outcome 1: Apply knowledge of the basic sciences (math, chemistry, and physics) and electrical engineering to identify, formulate, analyze/design, and solve Electrical Engineering problems [ABET Criterion 3a, e]; • Outcome 2: Design and conduct experiments and process tests and analyze and interpret experimental data [ABET Criterion 3b]; • Outcome 3: Use techniques, skills, and modern engineering tools [ABET Criterion 3k]; • Outcome 4: Design a system, component, or process to meet certain needs [ABET Criterion 3c] • Outcome 5: Function effectively on intra and inter disciplinary teams [ABET Criterion 3d]; • Outcome 6: Demonstrate an awareness of professional and ethical responsibility and of contemporary issues with relevance to global and regional issues [ABET Criteria 3h, c, f, j]; • Outcome 7: Communicate effectively in English in oral, written, and graphical formats [ABET • Criterion 3g]; • Outcome 8: Demonstrate awareness of, and engage in, life-long learning and self-education [ABET • Criterion 3i]; • Outcome 9: Demonstrate knowledge of probability and statistics, and advanced mathematics, typically including differential equations, and linear algebra [ABET Criterion 3l]. Program Facilities The EE Department has separate laboratories in MEN and WOMEN campus . The following labs are currently located in the Engineering Labs Building 3 (RUWAIS building ) in MEN campus and Arzanah campus (building 8) on the Sas Al Nakhl campus in Abu Dhabi. • • • • • • • • • • • Electric Circuits Lab; Electronics Circuits lab; Digital Electronic Circuits Lab; Microprocessors and Microcontrollers Lab; Industrial Automation Lab; Electric Machines Lab; Feedback Control Lab; Instrumentation and Measurements Lab; Signals and Systems Lab; Computer Lab; and Electrical workshop In addition to the above teaching laboratories the department also has set up three research laboratories namely power electronics and drives laboratory, Renewable energy laboratory and high voltage laboratory. 58 Professional Chapters and Clubs The student chapter of the Electrical and Electronics Engineers (IEEE) and the IEEE Women Affinity Group were established in 2007 and 20008 respectively. Their purpose is to provide students with the opportunity to be actively involved in their professional society. The chapter raises awareness about the profession and provides students with leadership opportunities. The PI IEEE chapter is actively involved in local and regional events organizing lectures and field trips, participating in conference and competitions, and involved in social activities and community services. The IEEE student members have won several national and international awards for the design and community service projects and have actively participated in local, regional and international conferences. Degree Requirements The Electrical Engineering Program begins with basic studies in engineering science coupled with fundamental studies in electrical engineering. The program continues with advanced courses in power, and controls and instrumentations engineering. To reinforce the principles and concepts introduced in the classroom, the program incorporates extensive hands-on laboratory work, design experiences to apply learned knowledge to solve representatives of real-world problems, and an environment that stresses teamwork and leadership. In addition, the program emphasizes the development of computer, and oral and written communication skills. The Electrical Engineering Program features a summer internship in industry where students will gain significant exposure to the petroleum processing industries in the Middle East and elsewhere in the world. The Electrical Engineering Program requires 130 credits to graduate distributed as follows: 53 credits in General Education Requirements, 68 credits in Major Requirements, at least 6 credits in Major Electives (at the 400-level) and 3 credits in Technical Electives. Program of Study for Electrical Engineering Term Fall Spring Course Code Course Title Freshman Year Credit CHEM 101 COMM 101 ENGR 101 General Chemistry I Communication I Introduction to Engineering in Petroleum Industry 4 4 3 MATH 111 TOTAL H&SS 111 COMM 151 MATH 161 PHYS 191 HFIT 111 TOTAL Calculus I 4 15 3 4 4 4 1 16 Islamic Studies Communication II Calculus II Physics I – Mechanics Personal Health and Fitness 59 Sophomore Year Fall Spring ELEG 205 ELEG 206 MATH 212 PHYS 241 STPS 201 TOTAL ELEG 305 ELEG 380 H&SS 251 MATH 261 STPS 251 TOTAL Electric Circuits I Introduction to computer Programming Calculus III Physics II – Electromagnetism and Optics Strategies for Team-Based Engineering Problem Solving I 4 3 3 4 3 17 4 4 3 3 3 17 Electric Circuits II Logic and Digital Design Principles of Economics Differential Equations Strategies for Team-Based Engineering Problem Solving II Junior Year Fall Spring Summer ELEG 310 ELEG 330 ELEG 325 ELEG 360 MATH 241 TOTAL ELEG 315 ELEG 350 ELEG 385 TECH XXX H&SS XXX TOTAL ELEG 397 Engineering Electromagnetics Electric Machines Electronic Devices and Circuits Feedback Control Systems Probability and Statistics for Engineers Signals and Systems Power Systems Analysis Microprocessors and Microcontrollers Technical Elective I Humanities and Social Sciences Elective I Electrical Engineering Internship 3 4 4 4 3 18 3 3 4 3 3 16 3 Senior Year Fall Spring ELEG 410 Fundamentals of Power Electronics 3 ELEG 440 ELEG 490 ELEG 4XX H&SS XXX TOTAL ELEG 390 ELEG 465 ELEG 491 ELEG 4XX TOTAL Instrumentation and Measurement 4 2 3 3 15 3 4 3 3 13 130 Electrical Engineering Design Project I Major Elective I Humanities and Social Sciences Elective II Data Communication Industrial Automation Electrical Engineering Design Project II Major Elective II TOTAL CREDIT HOURS 60 Electrical Engineering Major Electives (at least 6 credits) ELEG 420 Modern Control Systems 3 ELEG 450 ELEG 458 ELEG 460 ELEG 470 ELEG 475 ELEG 480 Electric Power Distribution Systems Electric Power Quality Digital Signal Processing Advanced Power Electronics Power Systems Protection and Relays Digital Control Systems 3 3 3 3 3 3 ELEG 493 Special Topics in Electrical Engineering 1-4 Electrical Engineering Technical Electives (at least 3 credits) MATH 361 MATH 365 MATH 461 PHYS 341 CHEM 102 Advanced Engineering Mathematics Numerical Methods Linear Algebra Modern Physics with Applications General Chemistry II 3 3 3 3 4 Courses not on the list require approval from the Electrical Engineering Program Chair. For a list of H&SS Elective courses, refer to the Arts and Sciences Program section of this document. 61 62 Material Science & Engineering Bachelor of Science in Metallurgical Science & Engineering Bachelor of Science in Polymer Science & Engineering Mission and Description The mission of the Materials Science and Engineering Program is as follows: The Materials Science and Engineering undergraduate program will be committed to continuous improvement in the quality of teaching, research and service and providing quality Science and Engineering education with sufficient scope to include the basic and specialized training necessary for the current and emerging needs of the society. The program will carry the responsibility to contribute to the advancement of knowledge by conducting research at the cutting edge of science and technology. As part of its mission, the program will promote and nurture the spirit of commitment, initiative and collegiality among faculty and across the whole institute. Program Educational Objectives: The educational objectives of the Materials Science and Engineering Program at the Petroleum Institute are derived from the Institutional Mission Statement, the Institutional Goals, and the Institutional Profile of the PI Graduate. These are: • To teach the students professional and ethical attitudes, effectiveness in communication and teamwork and an ability to take responsibility and actively contribute to the societal development. • To educate the students across the spectrum of fundamental and applied materials science and engineering, enabling them to solve engineering problems related to material behavior, properties and processing, hence satisfying the sponsor’s business goals. • To provide the students with a quality education in an academic environment committed to excellence and innovation that fosters leadership, professionalism and life-long learning and successful engineering careers. • To prepare the students with sufficient scientific and engineering breadth to design and develop innovative solutions to materials problems in engineering systems, trough industrial partnerships and collaboration with international institutions. Program Outcomes The program outcomes used to achieve the program objectives follow the ABET Criterion 3a-k, which are given below. They express what the students will be able to do upon the graduation from the Petroleum Institute. • Mastery of the knowledge, techniques, skills, and modern tools of their discipline [ABET Criterion 3a]; • Ability to apply current knowledge, and adapt to emerging applications of mathematics, science, engineering, and technology [ABET Criterion 3b]; • Ability to conduct, analyze, and interpret experiments, and apply results to improve processes [ABET Criterion 3c]; • Ability to apply creativity in the design of systems, components, or processes appropriate to program objectives [ABET Criterion 3d]; • Ability to function effectively on teams [ABET Criterion 3e]; • Ability to identify, analyze, and solve technical problems [ABET Criterion 3f]; • Ability to communicate effectively [ABET Criterion 3g]; • Recognize the need for, and an ability to engage in lifelong learning [ABET Criterion 3h]; • Ability to understand professional, ethical, and social responsibilities [ABET Criterion 3i]; • Respect for diversity, and a knowledge of contemporary professional, societal, and global issues related to the discipline [ABET Criterion 3j]; and • Commitment to quality, timeliness, and continuous improvement [ABET Criterion 3k]. 63 Degree Requirements The Materials Science and Engineering Program contains two separate degrees, one in Metallurgical Science and Engineering and the other in Polymer Science and Engineering. Materials Science and Engineering Curriculum The Materials Science and Engineering undergraduate program is designed to give the students a rigorous education in the fundamentals of materials and their applications and focus on the structure/properties/processing relationship, the principles and applications of materials’ processing, and the concepts of materials design and selection to address industrial challenges. The curriculum covers various types of materials with particular attention to metallic and polymeric materials. Both theory and practice are emphasized with a significant number of integrated laboratory courses, representing about 20% of the overall course time. Students graduating from this program will be ready to accept various industrial positions including in production, manufacturing, research & development and management, in both the basic and advanced materials industries. Such a curriculum will also prepare students for graduate education and other more advanced and specialized academic assignment in material-related disciplines. Curriculum Plan The Materials Science and Engineering program will follow a four-year cycle. During the first two years the freshman and sophomore students will follow the Arts & Sciences program, where fundamental sciences will be covered including math, physics and chemistry (details below). The students can choose between the two degrees offered in the Materials Science and Engineering program: • Metallurgical Science and Engineering • Polymer Science and Engineering This 4-year cycle can be preceded by two or three semesters of the ABP, which provides students with instruction in pre-calculus mathematics, physical sciences (chemistry, physics and geosciences), computing skills, and English. Program of Study for Metallurgical Science and Engineering Degree Term Course Code Course Title Credit Freshman Year Fall CHEM101 General Chemistry I 4 COMM101 Communication I 4 MATH111 Calculus I 4 ENGR101 Introduction to Engineering in the Petroleum Industry 3 HFIT 111 Personal Health & Fitness 1 PEEG201 Intro to Petroleum Industry 3 TOTAL 19 Spring CHEM102 General Chemistry II 4 COMM151 Communication II 4 MATH161 Calculus II 4 MATH161 Calculus II 4 TOTAL 16 64 Sophomore Year Fall CHEM211* Organic Chemistry I 4 MATH212 Calculus III 3 PHYS241 Physics II – Electromagnetism and Optics 4 STPS201 Strategies for Team-Based Engineering Problem Solving I 3 H&SS251 Principles of Economics 3 TOTAL 17 Spring MSEG334 Materials Science 3 MSEG380 Introduction to Polymer Science and Engineering 3 MATH Metallurgical Process Calculations 3 MATH261 Differential Equations 3 STPS 251 Strategies for Team-Based Engineering Problem Solving II 3 H&SS111 Islamic Studies 3 TOTAL 18 Junior Year Fall MSEG3XX Transport Phenomena 3 MSEG3XX Physical Metallurgy 3 MSEG3XX Thermodynamics of Materials 3 MSEG3XX Microstructure of Materials 3 MSEG3XX Basic Mechanics 3 HSS3XX HSS Elective 3 TOTAL 18 Spring MSEG3XX Phase Equilibrium & Transformation 3 MSEG3XX Corrosion & Oxidation of Metals 3 MSEG3XX Materials Characterization 2 MSEG3XX Extractive Metallurgy 3 MSEG3XX Metal Forming & Processes 3 MSEG3XX Material Kinetics 3 TOTAL 17 Summer MSEG399 Internship 3 Senior Year Fall MSEG4XX Introduction to Surface Eng. 3 MSEG4XX Non-Ferrous Metallurgy 3 MSEG4XX Senior Design I 3 MSEG4XX Steel Making Technologies 3 MSEG4XX Technical Elective 3 TOTAL 17 Spring MSEG4XX Materials Selection in Mechanical Design 3 MSEG4XX Metallurgical Application 3 MSEG4XX Senior Design II 3 TBA Technical Elective 3 TBA Technical Elective 3 TOTAL 15 Total Credit Hours 136 65 Program of Study for Polymer Science Engineering Degree Term Course Code Course Title Credit Freshman Year Fall CHEM101 General Chemistry I 4 COMM101 Communication I 4 MATH111 Calculus I 4 ENGR101 Introduction to Engineering in the Petroleum Industry 3 HFIT111 Personal Health & Fitness I 1 PEEG201 Intro to Petroleum Industry 3 TOTAL 19 Spring CHEM102 General Chemistry II 4 COMM151 Communication II 4 MATH161 Calculus II 4 PHYS191 Physics I - Mechanics 4 TOTAL 16 Sophomore Year Fall CHEM201 Organic Chemistry I 4 MATH212 Calculus III 3 PHYS241 Physics II – Electromagnetism and Optics 4 STPS201 Strategies for Team-Based Engineering Problem Solving I 3 H&SS251 Principles of Economics 3 TOTAL 17 Spring MSEG334 Materials Science 3 MSEG380 Introduction to Polymer Science and Engineering 3 MATH Probability and Statistics 3 MATH261 Differential Equations 3 STPS 251 Strategies for Team-Based Engineering Problem Solving II 3 H&SS111 Islamic Studies 3 TOTAL 18 Junior Year Fall MSEG3XX Transport Phenomena 3 MSEG3XX Polymer Physics 3 MSEG3XX Thermodynamics of Polymers 3 MSEG3XX Rheology 3 MSEG3XX Polymer Chemistry and Reaction Engineering 3 MSEG3XX Polymer Chemistry and Reaction Engineering Lab 2 TOTAL 17 Spring MSEG3XX Basic Mechanics 3 MSEG3XX Polymer Properties 3 MSEG3XX Polymer Properties Lab 2 MSEG3XX Polymer Processing I 3 MSEG3XX Polymer Processing Lab I 2 HSSXXX HSS Elective 3 TOTAL 16 66 Summer MSEG399 Internship 3 Senior Year Fall MSEG4XX Senior Design I 3 MSEG4XX Composite Materials 3 MSEG4XX Polymer Processing II 3 MSEG4XX Polymer Processing Lab II 3 MSEG4XX Polyolefin Technology 2 TBA Technical Elective 3 TOTAL 17 Spring MSEG4XX Senior Design II 3 MSEG4XX Polymer Material Design 3 MSEG4XX Polymer Product Design 3 TBA Technical Elective 3 TBA Technical Elective 3 TOTAL 15 Total Credit Hours 136 67 Mechanical Engineering Program Bachelor of Science in Mechanical Engineering Mission and Description The mission of the Mechanical Engineering Department at the Petroleum Institute is: “To support the advancement of the petroleum and energy industries in the United Arab Emirates through excellence in education and research in the field of mechanical engineering.” Mechanical engineering is an essential discipline in the production and processing of petroleum and natural gas, and the broader energy sector at large. We are dedicated to invest time and resources in educating students with the expectation that they will develop as leading experts in their respective fields of expertise and long-term contributors to the industrial sponsors, the UAE, and beyond. The Mechanical Engineering undergraduate Program at the Petroleum Institute is designed to give students a rigorous education in the fundamentals of the science of engineering mechanics, and specific training in applications of mechanical engineering in the oil and gas industries. The program incorporates extensive laboratory work which is used to reinforce the principles and concepts explored in the classroom. Educational Objectives The ME program strives to prepare graduates who after the first few years of graduation: • Will have successful careers in mechanical engineering with a particular focus on applications in the petroleum and energy industries. • Will progress rapidly towards the satisfactory attainment of ADNOC’s competency targets in mechanical engineering. • Will continue professional and personal growth through research and educational activities. Student Learning Outcomes (SLOs) The Mechanical Engineering undergraduate program uses the Qualification Framework (QF) Emirates level 7 Student Learning Outcomes (SLOs) to demonstrate achievement of the program educational objectives. These outcomes express what the ME students will be able to do upon graduation from The Petroleum Institute. The Student Learning Outcomes are given below with the corresponding ABET outcome. On successful completion of the undergraduate program, the graduate will be able to: Knowledge • K1: Apply knowledge of mathematics, science and engineering (ABET SLO (a)) • K2: Demonstrate a knowledge of the impact of engineering solutions in a global, economic, environmental, and societal context (ABET SLO (h)) • K3: Demonstrate an awareness of contemporary issues (ABET SLO (j)) Skill • S1: Design and conduct experiments, as well as analyze and interpret data (ABET SLO (b)) • S2: Design a system, component, or process to meet desired needs within realistic constraints, such as economic, environmental, social, political, ethical, health and safety, manufacturability, and sustainability (ABET SLO (c)) • S3: Identify, formulate, and solve engineering problems (ABET SLO (e)) • S4: Communicate effectively orally and in writing and deploy a range of presentation 68 techniques within workplace settings (ABET SLO (g)) • S5: Use the techniques, skills, and modern engineering tools necessary for engineering practice (ABET SLO (k)) • S6: Select and deploy a range of information retrieval techniques (ABET SLOs (i,g)) • S7: Demonstrate successful project management skills (ABET SLO (f)) Competence Autonomy and responsibility • C1: Work independently as well as part of a team in a range of contexts (ABET SLO (d)) • C2: Take and defend positions to formulate creative solutions to problems (ABET SLOs (c,g)) Role in context • C3: Demonstrate professional and ethical attributes relevant to their role (ABET SLO (f)) Self-development • C4: Take responsibility for his/her own future learning needs in new situations (ABET SLO (i)) • C5: Learn from experiences gained in different contexts and assimilate new knowledge and skills into their practice (ABET SLO (i, f)) Program Facilities The Mechanical Engineering Program laboratories are located in the Arzanah and Ruwais Buildings. They include the following: • Machine Shop and Manufacturing Laboratory • Measurement and Instrumentation Laboratory • Computer Simulation Laboratory • Materials Science Laboratory • Mechatronics Laboratory In addition to the teaching laboratories listed above, following research laboratories are available on campus: • Robotics, Automation & Mechatronics (RAM) Lab • Energy and Multiphase Transport (EMT) Lab • Mechanics, Materials, and Manufacturing (3M) Lab • Solar and Weather Observation (SWO) Lab • Mechatronics and Integrated Sensors (MIS) Lab Professional Chapters and Clubs Three student societies currently exist within the ME department. They are: • American Society of Mechanical Engineers (ASME) Student Section • American Society of Heating, Refrigerating, and A/C Engineers (ASHRAE) Student Section • Emirates Society of Energy (ESE) Student Section 69 Student societies have been involved in numerous ME activities including organizing social events, exhibitions, promotional displays, and student study sessions. Activities planned each academic year for student societies, include: • Promoting student sections and increasing membership. • Organizing professional development seminars and presentations. • Planning educational field trips and recreational outings. In addition to the above student activities, the ME department has created three technical extracurricular activities for its male and female students to further promote science, engineering design, and life-long learning. These activities allow ME students to compete in the following international events: • Baja SAE • World Solar Car Challenge • Hybrid-Electric Grand Prix Degree Requirements The field of Mechanical Engineering deals with the science and engineering of mechanical devices and processes. Accordingly, the degree program begins with basic studies in engineering science including statics, dynamics, fluid mechanics, thermodynamics, and mechanics of materials. The program continues with advanced courses in machine design, computer-aided engineering, heat transfer, systems dynamics & control, engineering vibration and turbomachinery. The design experience in the ME program is introduced progressively at several stages in the curriculum from two introductory design courses (STPS 201 and STPS 251) in Sophomore year to two-semester capstone mechanical design sequence courses (MEEG 490 and MEEG 491) in the senior year. The design curriculum emphasizes design, communication and computer-aided system, and component design strategies. The program features an industrial summer internship where students gain exposure to the petroleum and natural gas processing industries in the Middle East or elsewhere in the world. The Mechanical Engineering Program requires 134 credits to graduate distributed as follows: 45 credits in General Education Requirements, 65 credits in Major Requirements, 12 credits in humanities and social sciences, at least 6 credits in Major Electives and maximum of 6 credits in Technical Electives. 70 Program of Study for Mechanical Engineering Term Fall Spring Course Code CHEM 101 COMM 101 ENGR 101 MATH 111 TOTAL PHYS 191 COMM 151 MATH 161 HFIT 111 H&SS 111 TOTAL Course Title Freshman Year General Chemistry I Communication I Introduction to Engineering in the Petroleum Industry Calculus I Physics I - Mechanics Communication II Calculus II Personal Health and Fitness Islamic Studies Credit 4 4 3 4 15 4 4 4 1 3 16 Sophomore Year Fall Spring MEEG 201 H&SS 251 MEEG 275 MATH 212 PHYS 241 STPS 201 TOTAL MATH 261 MEEG 205 MEEG 324 MEEG 344 MEEG 365 STPS 251 TOTAL Engineering Statics Principles of Economics Basic Measurement Laboratory Calculus III Physics II – Electromagnetism and Optics Strategies for Team-Based Engineering Problem Solving I Differential Equations Introduction to Modern Mechanical Engineering Engineering Dynamics Mechanics of Materials Thermodynamics Strategies for Team-Based Engineering Problem Solving II 3 3 2 3 4 3 18 3 2 3 3 4 3 18 71 Junior Year Fall Spring Summer ELEG 205 Electric Circuits I 4 MEEG 221 Engineering MATLAB 3 MEEG 334 Materials Science 4 MEEG 345 MEEG 354 TOTAL MATH 241 MEEG 374 MEEG 376 MEEG 384 MEEG 385 TECH XXX TOTAL MEEG 397 Introduction To Manufacturing Processes Fluid Mechanics 3 3 17 3 3 2 3 3 3 17 3 Probability and Statistics Machine Design Core Measurements Laboratory System Dynamics and Control Heat Transfer Technical Elective I Mechanical Engineering Internship Senior Year Fall Spring MEEG 404 Introduction to Finite Element Analysis 3 MEEG 444 MEEG 490 MEEG XXX H&SS XXX TOTAL MEEG 459 MEEG 491 TECH XXX MEEG XXX H&SS XXX TOTAL Engineering Vibration Mechanical Engineering Design Project I Major Elective I Humanities and Social Sciences Elective I 3 3 3 3 15 3 3 3 3 3 15 134 Turbomachinery Mechanical Engineering Design Project II Technical Elective II Major Elective II Humanities and Social Sciences Elective II TOTAL CREDIT HOURS Mechanical Engineering Major Electives (at least 6 credits) Taken during Junior and senior years 72 MEEG 380 Introduction to Polymer Science 3 MEEG 410 Viscous and Boundary Layer Flows 3 MEEG 439 Machine Dynamics 3 MEEG 454 Refrigeration, Air Conditioning and Cryogenics 3 MEEG 480 Renewable Energy Technologies 3 MEEG 485 Introduction to Robotics 3 Mechanical Engineering Technical Electives (maximum 6 credits) CHEM 102 Chemistry II 4 CHEG 313 Experimental Design and Analysis 3 ELEG 305 Electric Circuits II 4 ELEG 315 Signals and Systems 3 ELEG 325 Electronic Devices and Circuits 4 ELEG 330 Electric Machines 3 HSEG 401 Introduction to HSE Engineering 3 HSEG 405 System Safety Engineering and Risk Management 3 MATH 361 Advanced Engineering Mathematics 3 MATH 461 Linear Algebra 3 PEEG 321 Drilling Engineering 3 PEEG 342 Production Facilities 3 PEEG 460 Petroleum and Risk Economics Analysis 3 PHYS 393 Special Topics in Physics 3 • Courses not on the list require approval from the Mechanical Engineering Department Chair. • For a list of H&SS Elective courses, refer to the Arts and Sciences Department section of this document. 73 74 Petroleum Engineering Program Bachelor of Science in Petroleum Engineering Mission and Description The mission of the Petroleum Engineering Program at the Petroleum Institute is to become a leading international center of excellence in education, training, research and professional service dedicated to serving the competence, training and technology development needs of the petroleum industry in general, and ADNOC and other allied sponsors in particular. Our mission is to provide a platform for life-long learning while also emphasizing the importance of interdisciplinary approach, ethical conduct, and health, safety and environmental issues. The Petroleum Engineering Program at the PI has a modern curriculum that emphasizes not only petroleum engineering fundamentals but also the business processes applied to reach optimal engineering solutions for field development and operations. With access to the local operating company facilities, our well-equipped state-of-the-art modern laboratory and computer facilities, we are uniquely positioned to offer a curriculum that is well balanced and hands on. We are also accredited to offer IWCF certification and training for drilling engineers. Course content, projects and other assignments are selected to help prepare graduates to launch careers within ADNOC and other allied sponsors as willing and eager contributors, equipped with knowledge and skills of basic engineering and science, fundamental understandings of reservoir, well, production and surface facilities. Educational Objectives The educational objectives of the Petroleum Engineering Department at the PI are derived from the institutional mission statement, the institutional goals, and the institutional profile of the PI graduate. The Petroleum Engineering Department will produce graduates who would be able to: • Demonstrate highest levels of technical, ethical and behavioral competencies. • Develop and establish themselves as Engineers and Supervisors. • Become a major source of competent Engineers to serve the country’s objectives. • Undertake graduate studies and become involved in research and development. Student Outcomes The student educational outcomes correspond to the ABET outcomes a-k. Outcomes d and j were modified to better reflect the disciplines of petroleum engineering. The student educational outcomes require that graduates must have: a) An ability to apply knowledge of mathematics, science, and engineering. b) An ability to design and conduct experiments, as well as to analyze and interpret data. c) An ability to design a system, component, or process to meet desired needs within realistic constraints such as economic, environmental, social, political, ethical, health and safety, manufacturability, and sustainability. d) An ability to function on multidisciplinary teams. The petroleum disciplines judged relevant to petroleum engineering are: • Petroleum sub-disciplines: drilling, production, reservoir engineering and formation evaluation • Knowledge of project management and data integration. • Geosciences disciplines 75 e) An ability to identify, formulate and solve engineering problems. f) An understanding of professional and ethical responsibility. g) An ability to communicate effectively. h) The broader education necessary to understand the impact of engineering solutions in a global, economic, environmental, and social context. i) A recognition of the need for, and an ability to engage in life-long learning. j) A knowledge of contemporary issues pertaining to energy k) An ability to use the techniques, skills, and modern engineering tools necessary for engineering practice. Program Facilities The following Petroleum Engineering Program laboratories are currently operational for teaching and research: • Analytical Instrument Laboratory • Core Preparation Laboratory • Drilling Fluids Laboratory • Drilling Simulation Laboratory • Fluid Properties Laboratory • Reservoir Simulation Laboratory • Rock Mechanics Laboratory • Rock Properties Laboratory • Production and Facilities Laboratory Professional Chapters and Clubs The Student Chapter of the Society of Petroleum Engineers (SPE) opened in 2004 and is affiliated with the Abu Dhabi SPE section. Activities of the PI SPE Student Chapter are broadly divided into technical and social functions. Examples of major technical activities include sponsoring students to conferences and Education Weeks organized annually by SPE in conjunction with major oil and gas conferences in the region, field trips, company visits, technical presentations delivered by industry professionals or student paper contests that offer students the chance to showcase their research skills, competing with other students for honors both regionally and internationally. Social activities include the annual Petroleum Engineering Sports Day, BBQ dinners, dhow cruises, visits to other chapters, etc. Degree Requirements The Petroleum Engineering Program at the Petroleum Institute is designed to give students a rigorous education in the fundamentals of petroleum engineering science and specific training in applications of petroleum engineering to the production of hydrocarbon resources in the oil and gas industries. The program incorporates extensive laboratory work which is used to reinforce the principles and concepts used in the classroom. The program features a summer internship in industry where students will gain significant exposure to the petroleum production and processing industries in the Middle East or elsewhere in the world. The Petroleum Engineering Program requires 133 credits to graduate distributed as follows: 53 credits in General Education Requirements, 74 credits in Major Requirements and at least 6 credits in Major or pre- approved Technical Electives. 76 Program of Study for Petroleum Engineering Term Fall Spring Course Code CHEM 101 COMM 101 MATH 111 ENGR 101 HFIT 111 TOTAL CHEM 102 COMM 151 MATH 161 PHYS 191 TOTAL Course Title Freshman Year General Chemistry I Communication I Calculus I Intro to Engineering in the Petroleum Industry Personal Health and Fitness General Chemistry II Communication II Calculus II Physics I – Mechanics Credit 4 4 4 3 1 16 4 4 4 4 16 Sophomore Year Fall Spring MEEG 222 MATH 212 PGEG 221 PEEG 214 PEEG 215 PHYS 241 STPS 201 TOTAL MEEG 302 MATH 261 PEEG 216 PEEG 217 PEEG 252 PGEG 220 STPS 251 TOTAL Introduction to Engineering Thermodynamics Calculus III Introduction to Geology and Geophysics Reservoir Rock Properties Reservoir Rock Properties Laboratory Physics II - Electromagnetism and Optics Strategies for Team-Based Engineering Problem Solving I Fluid Mechanics & Heat Transfer Differential Equations Reservoir Fluid Properties Reservoir Fluid Properties Laboratory Mechanics of Materials for PE Geology of the Middle East Strategies for Team-Based Engineering Problem Solving II 3 3 3 2 1 4 3 19 3 3 2 1 3 3 3 18 Junior Year Fall Spring Summer H&SS 251 PEEG 314 PEEG 321 PEEG 331 PGEG 311 TOTAL PEEG 324 PEEG 325 PEEG 334 PEEG 341 PEEG 460 PEEG 315 TOTAL PEEG 397 Principles of Economics Well logging Drilling Engineering I Reservoir Engineering I Sedimentary Petrology Drilling Engineering II Drilling Engineering II Laboratory Reservoir Engineering II Completion and Workover Petroleum Economics and risk Analysis Reservoir Characterization Petroleum Engineering Internship 3 3 3 3 4 16 2 1 4 3 4 3 17 3 77 Senior Year H&SS 111 Fall Spring Islamic Studies PEEG 342 PEEG 443 PEEG 490 PEEG or TECH XXX PEEG 436 TOTAL PEEG 491 PEEG or TECH XXX H&SS XXX H&SS XXX Production Facilities Production Systems Design and Analysis Petroleum Engineering Design Project I Major or Technical Elective I Well Testing 3 3 3 1 3 Petroleum Engineering Design Project II Major or Technical Elective II 3 16 3 3 Humanities and Social Sciences Elective I Humanities and Social Sciences Elective II 3 3 TOTAL TOTAL CREDIT HOURS 12 133 Petroleum Engineering Major Electives (up to 6 credits) PEEG 420 PEEG423 PEEG 424 PEEG 425 PEEG437 PEEG 445 PEEG 456 PEEG 293/393/493 PEEG 394/494 PEEG 396/496 78 3 Well Treatment Horizontal and Multilateral Well Technology Underbalanced Drilling Technology Pressure Control Natural Gas Engineering Production Enhancement Petroleum Related Rock Mechanics Special Topics in Petroleum Engineering 3 3 3 3 3 3 1-4 Research Topics in Petroleum Engineering Independent Study in Petroleum Engineering 1-4 1-6 Petroleum Engineering Technical Electives (up to 6 credits) CHEG 416 Corrosion Engineering 3 CHEG/ MEEG380 CHEM 211 CHEM 212 ELEG 205 Introduction to Polymer Science and Engineering 3 Organic Chemistry I Organic Chemistry II Electric Circuits I Technology Development Ventures and Entrepreneurship 3 3 4 3 MATH 241 Probability and Statistics 3 MATH 361 MATH 365 MATH 461 MEEG 334 MEEG 374 PGEG 321 PGEG 323 PGEG 351 PGEG 361 PGEG 451 PHYS 341 Engineering Mathematics Numerical Methods Linear Algebra Materials Science Machine Design Structural Interpretation Remote sensing for Earth Science Applications and GIS Petroleum Geophysics Sedimentology and Stratigraphy Environmental Geology Modern Physics with Applications 3 3 3 3 3 4 2 4 3 3 3 ENGR 496 • Courses not on the list require approval from the Petroleum Engineering Program Chair. • For a list of H&SS Elective courses, refer to the Arts and Sciences Program section of this document. 79 80 81 Petroleum Geosciences Program Bachelor of Science in Petroleum Geosciences Concentration in Petroleum Geophysics Mission and Description The mission of the Petroleum Geosciences Program at the Petroleum Institute is to provide a highquality education in petroleum geology and geophysics and to produce graduates for successful and socially and ethically responsible careers in the petroleum industry that meet or exceed the needs and expectations of ADNOC and other industry sponsors. The Petroleum Geosciences Program at The Petroleum Institute is a blend of geology and geophysics as they relate to the discovery and exploitation of oil and gas. A concentration in Petroleum Geophysics is offered for students who wish to focus on this specific area of the geosciences. Strengths of the Petroleum Geosciences curricula include an emphasis on geosciences project work and use of modern software applications. In addition, emphasis is placed on the development of “soft skills” during coursework. Petroleum Geosciences laboratories, including a computer laboratory, are well equipped, and up-to-date geophysical equipment is available for field exercises. The program features a summer field geology course. Students who successfully complete the Bachelor of Science program will be able to enter the petroleum industry as petroleum geologists or geophysicists, and have a solid educational base if they decide to continue to a graduate program. Educational Objectives The Petroleum Geosciences graduates will accomplish the following: • Apply geological and geophysical knowledge and skills to recognize exploration, development, and production problems and design technically, economically, and environmentally sound solutions to find and maximize the value of petroleum resources of the UAE. • Contribute effectively, including in leadership roles, in multi-disciplinary exploration, development and production teams. • Function ethically and with integrity such that society and industry benefit from their work as petroleum geoscientists. • Continue personal and professional growth through self-education. • Meet or exceed expectations of the ADNOC Group and corporate sponsors in attaining technical and personal competencies. Student Learning Outcomes On completion of the Petroleum Geosciences Program, graduates will be able to. 1. Apply knowledge of math, chemistry, physics, geology, and geophysics to solve petroleum geosciences problems; 2. apply knowledge to formulate solutions to geoscience problems involving design of geophysical surveys, acquisition and processing of geophysical data, and make geological interpretations from results; 3. apply 3-dimensional Earth models to solve exploration and production E&P-type issues from appropriate geological, petrophysical and geophysical data. 4. function effectively on multi-disciplinary teams; 5. demonstrate an awareness of the social, ethical, and professional responsibilities in the exploration and exploitation of energy and natural resources and a concern for major regional and global social and environmental issues; 6. demonstrate an ability to communicate in oral and written forms in English appropriate to the 82 petroleum and broad energy industry; 7. demonstrate recognition of the need for and an ability to engage in continual lifelong education. Additional outcome for the Petroleum Geophysics Concentration: 8. Analyze, quantitatively, the errors, limitations, and uncertainties in data. Program Facilities The Petroleum Geosciences’ fourteen laboratories are located in the Arzanah, Bu Hasa, and Ruwais Buildings. The laboratories in the Arzanah Building include geology and geophysics teaching laboratories, dedicated core- lay-out areas, laboratories for sample and equipment preparation, and a dedicated geosciences computer laboratory equipped with a wide range of industry-standard geoscience software. In the Ruwais and Bu Hasa Buildings the laboratories focus on undergraduate teaching and research support. These laboratories include a scanning electron microscopy laboratory, a geosciences computing laboratory, petrographic microscopy laboratory and geophysical equipment storage and testing laboratory. Professional Chapters and Clubs American Association of Petroleum Geologists (AAPG) Student Chapter The American Association of Petroleum Geologists (AAPG) student chapter in the Petroleum Geosciences Program is the first AAPG Chapter established in the UAE. The PI’s AAPG student chapter provides a variety of programs and opportunities for students to have contact with the professional geosciences community, tohave access to unique learning and leadership opportunities, to receive member benefits and to be eligible for grants. The Geosciences Student Society (G.S.S) The Petroleum Geosciences Student Society aims to help and support students at the Petroleum Institute as they prepare to start their career within the Petroleum Geosciences. As well as supporting the next generation of geoscientists, the society also provides a range of social activities for geosciences students at the Petroleum Institute. Recent activities included guest seminars and lectures, field trips, social evenings and sporting events. Society of Exploration Geophysicists (SEG) and European Association of Geoscientists and Engineers (EAGE) PI Student Chapters The student chapter’s affiliation with SEG and EAGE provides a means of contact with the geosciences profession both inside and outside of academia. Active participation in the Student Chapters provides students with an opportunity to develop leadership and management skills. A sense of professionalism is developed by actively running an organization and networking with professionals. 83 Degree Requirements The Petroleum Geosciences Program requires 133 credits to graduate distributed as follows: 33 credits in Basic Sciences, 27 credits in General Education Requirements, 73 credits in Major Requirements, including 3 credits in Major or Technical Electives. The Concentration in Petroleum Geophysics requires 134 credits to graduate with 74 credits in Major Requirements. Basic sciences All PGS undergraduate students are required to take 3 math courses (calculus) for a total of 11 credits in math, 2 physics courses with laboratories (Physics I and II) for a total of 8 credits in physics and 2 chemistry courses with laboratories (General Chemistry I and II) for a total of 8 credits in chemistry. The above courses taught by the departments of mathematics, physics and chemistry total 27 credits. In addition, PGEG 221 (Introduction to Geology and Geophysics), which is a 3 credit course offered by Petroleum Geosciences, and MEEG 222 (Introduction to Engineering Thermodynamics), which is offered by the Mechanical Engineering Department within the PI, are 3 credit basic courses. This leads to a total of 33 credits in basic sciences which are required by students graduating in PGS. Geosciences Students begin their major study of petroleum geosciences topics in their freshman or sophomore year (depending on fall or spring entry) with PGEG 221 (3 credits). In addition, they take two courses from the Petroleum Engineering program: PEEG 216 (2 credits), and PEEG 217 (1 credit). For the junior year, at least 3 courses in geosciences are offered in each semester. Including courses such as STPS 201 and STPS 251 that focus on team-based problem solving, this leads to a total of 73 credits (74 for the Concentration in Petroleum Geophysics) in geosciencesspecific topics. Some courses are taken with students in the Petroleum Engineering Program. The Program incorporates extensive laboratory, field, and project work. A highlight of the program is a Field Petroleum Geology course (PGEG 397) to Italy and Spain. Students of the Concentration in Geophysics will complete an Industry Internship during the summer between their junior and senior years. General Education program The general education component which complements the technical content of the curriculum is required for all PI students, including PGS students. It consists of a total of 27 credits which are allocated among various topics that include Economics, Islamic Studies, Physical Education and Communication. 84 Program of Study for Petroleum Geosciences First Year Fall Semester Code Course Name Spring Semester Credit Hours 4 Hours a week Lecture 5 Lab 3 Code CHEM102 Course Credit Hours General Chemistry II 4 Hours a week Lecture 5 Lab 3 CHEM101 General Chemistry I COMM101 Communication I 4 5 0 COMM151 Communication II 4 5 0 ENGR101 3 2 3 MATH161 Calculus II 4 5 0 MATH111 Intro to Eng. in the Pet. Ind. Calculus I 4 5 0 PHYS191 Physics I 4 5 3 HFIT111 Pers. Health & Fitness 1 0.5 1.5 TOTAL 16 17.5 7.5 TOTAL 16 20 6 Second Year Fall Semester Code Course Name Spring Semester Hours a week Credit Hours Lecture Lab Code Course Hours a week Credit Hours Lecture Lab MEEG222 Int. to Eng. Thermo. 3 3 0 PEEG217 Res. Fluid Properties Lab 1 0 3 MATH212 Calculus III 3 4 0 PEEG216 Reservoir Fluid Properties 2 2 0 PGEG221 Int. to Geo. & Geophysics 3 2 3 PGEG230 Geological Maps 3 3 0 PHYS241 Physics II Strategies for Team-based Engineering Problem Solving 1 4 5 3 PGEG210 Earth Materials 3 2 3 3 2 3 PGEG220 Geo. of the Middle East 3 3 0 PGEG220L Geo. of the Mid. East Lab. 1 0 3 H&SS111 Islamic Studies 3 3 0 TOTAL 16 13 9 STPS201 TOTAL 16 13 9 Third Year Fall Semester Code Course Name Spring Semester Credit Hours Hours a week Lecture Lab Code H&SS251 Principles of Economics 3 3 0 STPS251 PGEG311 Sedimentary Petrology 4 3 3 PGEG351 PGEG321 Structural Geology 4 3 3 PGEG361 PGEG331 Igneous and Metamorphic Petrology 3 2 3 PGEG371 PGEG341 Paleontology 3 2 3 PGEG381 TOTAL 17 13 12 Summer Semester PGEG397 Course Hours a week Credit Hours Lecture Lab 3 2 3 4 3 3 3 2 3 4 3 3 Strategies for Team-based Engineering Problem Solving 2 Petroleum Geophysics Sedimentology & Stratigraphy Data Analysis & Geostatistics Rock Mechanics & Reservoirs TOTAL 3 2 3 17 12 15 Field Petrol. Geology 4 Field Work Fourth Year Fall Semester Code Course Name Spring Semester Hours a week Credit Hours Lecture Lab Code Course Hours a week Credit Hours Lecture Lab 0 PGEG401 Petrophysics & Logging 4 3 3 PGEG451 Environmental Geology 3 3 PGEG411 Reflection Seismology 4 3 3 PGEG461 Reservoir Charact. Project 4 2 6 H&SS H&SS Elective 3 3 0 PGEG471 Petrol. Systems Project 3 1 6 TBA Technical Elective 3 2 3 PGEG412 Seismic Reflection Interp. 4 3 3 H&SS H&SS Elective 3 3 0 TOTAL 14 11 9 TOTAL 17 12 15 Total Credit Hours: 133 85 Petroleum Geosciences Ma jor Electives (up to 3 credits) PGEG 323 Remote Sensing for Earth Science Applications and GIS 2 PGEG 413 Micropaleontology 3 Special Topics in Petroleum Geosciences 1-4 Research Topics in Petroleum Geosciences Independent Study in Petroleum Geosciences 1-4 1-6 PGEG 293/393/493 PGEG 394/494 PGEG 396/496 Petroleum Geosciences Technical Electives (up to 3 credits) CHEM 393 Microbiology and Environmental Chemistry for Engineers 3 MATH 261 Differential Equations 3 MATH 361 Engineering Mathematics 3 MATH 461 Linear Algebra 3 PEEG 331 Reservoir Engineering I 3 PHYS 341 Modern Physics with Applications 3 • Courses not on the list require approval from the Petroleum Geosciences Program Chair. • For a list of H&SS Elective courses, refer to the Arts and Sciences Program section of this document. 86 Program of Study for the Concentration in Petroleum Geophysics First Year Fall Semester Code Course Name Spring Semester Credit Hours Hours a week Code Course Lab 3 CHEM102 General Chemistry II Credit Hours Hours a week CHEM101 General Chemistry I 4 Lecture 5 4 Lecture 5 Lab 3 COMM101 Communication I 4 5 0 COMM151 Communication II 4 5 0 ENGR101 3 2 3 MATH161 Calculus II 4 5 0 MATH111 Intro to Eng. in the Pet. Ind. Calculus I 4 5 0 PHYS191 Physics I 4 5 3 HFIT111 Pers. Health & Fitness 1 0.5 1.5 TOTAL 16 17.5 7.5 TOTAL 16 20 6 Credit Hours Lecture Lab Second Year Fall Semester Code Course Name Spring Semester Hours a week Credit Hours Lecture Lab Code Course Hours a week MATH212 Calculus III 3 4 0 MATH261 Differential Equations 3 3 0 PGEG221 Introduction to Geology & Geophysics 3 2 3 PGEG230 Geological Maps 3 3 0 PHYS241 Physics II 4 5 3 PGEG210 Earth Materials 3 2 3 STPS201 Strategies forTeam-Based Engineering Problem Solving 1 3 2 3 PGEG220 Geology of the Middle East 3 3 0 H&SS111 Islamic Studies 3 3 0 PGEG220L Geology of the Middle East Lab 1 0 3 H&SS H&SS Elective 3 3 0 TOTAL 16 14 6 Course Credit Hours Lecture Lab 3 2 3 4 3 3 3 2 3 4 3 3 TOTAL 16 16 9 Third Year Fall Semester Code Course Name Spring Semester Credit Hours Hours a week Lecture Lab Code H&SS251 Principles of Economics 3 3 0 STPS251 PGEG300 Matlab for Earth Scientists Strategies forTeam-Based Engineering Problem Solving 2 3 2 3 PGEG351 Petroleum Geophysics PGEG311 Sedimentary Petrology 4 3 3 PGEG361 PGEG321 Structural Geology 4 3 3 PGEG371 PGEG411 Reflection Seismology 4 3 3 PGEG381 TOTAL 18 14 12 Summer Semester PGEG398 Hours a week Sedimentology & Stratigraphy Data Analysis & Geostatistics Rock Mechanics & Reservoirs TOTAL 3 2 3 17 12 15 Geophysics Internship 3 Internship Credit Hours Hours a week Lecture Lab 3 3 0 4 2 6 3 1 6 4 3 3 Reservoir Geophysics 4 3 3 TOTAL 18 12 18 Fourth Year Fall Semester Spring Semester Hours a week Credit Hours Lecture Lab PGEG400 Seismic Data Acquisition and Processing 4 3 3 PGEG451 PGEG402 Petrophysics & Logging 4 3 3 PGEG461 H&SS H&SS Elective 3 3 0 PGEG471 TBA Technical Elective 3 2 3 PGEG412 Code Course Name Code PGEG410 TOTAL Total Credit Hours: 14 11 9 Course Environmental Geology Reservoir Characterization Project Petroleum Systems Project Seismic Reflection Interpretation 134 87 Petroleum Geosciences Major Electives (up to 3 credits) PGEG 323 Remote Sensing for Earth Science Applications and GIS 2 PGEG 413 Micropaleontology 3 PGEG 293/393/493 PGEG 394/494 PGEG 396/496 Special Topics in Petroleum Geosciences Research Topics in Petroleum Geosciences Independent Study in Petroleum Geosciences 1-4 1-4 1-6 Petroleum Geosciences Technical Electives (up to 3 credits) CHEM 393 Microbiology and Environmental Chemistry for Engineers 3 MATH 361 MATH 461 PEEG 331 PHYS 341 Engineering Mathematics Linear Algebra Reservoir Engineering I Modern Physics with Applications 3 3 3 3 • Courses not on the list require approval from the Petroleum Geosciences Program Chair. • For a list of H&SS Elective courses, refer to the Arts and Sciences Program section of this document. 88 89 90 91 Course Descriptions This section includes course descriptions listed alphabetically by subject area. The descriptions provide information on subject, course codes, titles and level in the first line. This is followed by content, pre- requisites, co-requisites and restrictions, and finally lecture and lab hours and weight or credit hours as shown in the following example: CHEM 102 GENERAL CHEMISTRY II This course is a continuation of CHEM 101 and is designed to meet the requirements of students majoring in an engineering or science program that requires a strong background in chemistry. Topics include intermolecular forces, pure solids and liquids, properties of solutions, kinetics, equilibrium processes, chemical thermodynamics, and electrochemistry. This course is accompanied by a laboratory component that includes both quantitative and qualitative procedures. Prerequisite Co-requisite Restrictions Lecture/Lab/Credit: Key Subject code Course code 001 - 099 100 - 199 200 - 299 300 - 399 400 - 499 Title / Level Prerequisite Co-requisite Restrictions Hours CHEM 101, MATH 111 None None 3:3:4 The area of study or discipline e.g. CHEM = Chemistry Academic Bridge Program Freshman year e.g. 102 is a Freshman course Sophomore year Junior year Senior year Name of the Course e.g. General Chemistry II Description Course Content Course(s) students must have passed before enrollment e.g. CHEM 101 Courses students must have passed or be currently enrolled in along with this course Limitations on who may and may not take the course e.g. 3:3:4 = 3 class hours per week: 3 lab hours per week: 4 credit hours Academic Bridge Program Skills Courses English (ABPS) ABPS 010 ABP ENGLISH 1 In this course, students will develop the English language skills needed to meet the requirements of ABPS020. During the course, students will read general and academic texts and will listen to a variety of short conversations and lectures to help improve comprehension skills. Students will be taught to take notes, use critical thinking skills to write short texts based on course readings and lectures, present information orally, and develop study skills needed for university courses. Prerequisites: None Corequisites: None Restrictions: None 92 ABPS 020 ABP ENGLISH 2 In this course, students will develop the English language skills needed to meet the requirements of ABPS030. During the course, students will read general and academic texts and will listen to a variety of short conversations and lectures to help improve comprehension skills. Students will be expected to take notes and annotate academic texts, write short texts which require critical thinking based on course readings and lectures, present information orally, and develop test taking skills. Prerequisite: ABPS010 - ABP English 1 or IELTS 5/TOEFL IBT 36 Corequisites: None Restrictions: None ABPS 030 ABP ENGLISH 3 In this course, students will acquire the English language and academic skills needed to meet the requirements of the Petroleum Institute’s Freshman classes. During this course, students read a variety of texts, listen to a variety of short conversations and lectures, take notes and annotate academic texts, write short texts which require critical thinking based on course Readings and lectures, present Information orally and develop all-round test taking skills Prerequisite: ABPS020 ABP English 2 or IELTS 5.5/ TOEFL IBT 48 Corequisites: None Restrictions: None Degree Courses Chemical Engineering (CHEG) CHEG205 PRINCIPLES OF CHEMICAL ENGINEERING Introduction to the principles of conservation of mass and energy. Applications to chemical processing systems. Relevant aspects of computer-aided process simulation. Pre-requisites: CHEM102 Co-requisites: PHYS191 Restrictions: None Lecture/Lab/Credit: 4:0:4 CHEG212 COMPUTATIONAL METHODS IN CHEMICAL ENGINEERING Introduction to MATLAB and solution of engineering problems with applications in chemical engineering. Data representation, functions, plotting, matrix manipulations, structured programming (if statements, loops, functions), numerical integration and differentiation, curve fitting, differential equations, and symbolic mathematics. Pre-requisites: CHEG205 Co-requisites: MATH261 Restrictions: None Lecture/Lab/Credit: 3:0:3 93 CHEG232 FLUID MECHANICS Theory and application of momentum transport and fluid flow in chemical engineering. Fundamentals of microscopic phenomena and application to macroscopic systems. Relevant aspects of computer-aided process simulation. Pre-requisites: CHEG205 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 CHEG313 EXPERIMENTAL DESIGN AND ANALYSIS This course gives students the ability to solve important engineering problems by applying statistical tools. The course starts with description of random variables and probability distributions. The use of statistical decision-making tools is then discussed. The next section of the course covers application of empirical models to optimize engineering systems which is followed by application of designed experimentation. The last section coves application of statistical process control in process control, management of operating costs, and optimization in the transactional environment. Pre-requisites: MATH212 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 CHEG314 ENGINEERING ECONOMICS Analysis, costing, and economic evaluation of processes and projects applied to the chemical process industries. Investment analysis, rate of return, time value of money, discounted cash flow. Applications of the principles of depreciation, depletion, and amortization to analysis of the economic viability of projects. Pre-requisites: H&SS101 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 CHEG324 MASS TRANSFER Fundamentals of stage-wise and diffusional mass transport with applications to chemical engineering systems and processes. Relevant aspects of computer-aided process simulation. Pre-requisites: None Co-requisites: CHEG335 None Restrictions: None Lecture/Lab/Credit: 3:0:3 94 CHEG325 FUNDAMENTALS OF NANOTECHNOLOGY This course introduces students to the fundamental principles which govern product and process design in nano-engineering. In particular, the course will discuss such topics as building a nanoparticle by self-assembly, methods for nanoparticle characterization and stability, thermodynamics at nano scale, Brownian motion and diffusion of nanoparticles. Laboratory techniques to study nanoparticles and nanostructures will also be discussed. The course may contain a short laboratory project in the new light- scattering lab to measure nanoparticle average size and size distribution. Pre-requisites: CHEM331 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 CHEG332 CHEMICAL ENGINEERING THERMODYNAMICS Fundamentals of thermodynamics for application to chemical engineering processes and systems. Application of first and second laws to the analysis of thermodynamic cycles; multiphase equilibria of ideal and non-ideal systems, chemical reaction equilibrium and introduction to molecular thermodynamics. Pre-requisites: CHEG205 and CHEM 331 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 CHEG335 HEAT TRANSFER Theory and applications of energy transport: conduction, convection and radiation. Fundamentals of microscopic phenomena and application to macroscopic systems. Relevant aspects of computer-aided process simulation Pre-requisites: CHEG232 Co-requisites: CHEM331 Restrictions: None Lecture/Lab/Credit: 3:0:3 CHEG354 CHEMICAL ENGINEERING LABORATORY I This is the first in a sequence of two lab courses that covers laboratory work pertinent to thermodynamics, fluid mechanics, heat, and mass transfer. In this laboratory course, experiments relevant to fluid mechanics and thermodynamics are covered. Students run experiments and analyze laboratory data using appropriate statistical methods, and produce oral and written technical reports. Pre-requisites: CHEG232 Co-requisites: CHEG332 Restrictions: None Lecture/Lab/Credit: 0:3:2 95 CHEG380 INTRODUCTION TO POLYMER SCIENCE AND ENGINEERING Definitions, industry overview, nomenclature, basic organic chemistry of polymers, polymerization, molecular weight and molecular weight distribution. Basic polymer structure and thermo mechanical behaviour and structure property relationship. Mechanical properties, definitions, viscoelasticity, other mechanical properties. Basic rheology and introduction to polymer processing techniques, recycling. Concepts will be reinforced by the laboratory component of the course Pre-requisites: CHEM101, PHYS 191 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 2:3:3 CHEG381 POLYMER CHEMISTRY AND REACTION ENGINEERING This course introduces the chemistry of polymerization and the polymer manufacturing process. It begins with basic concepts about polymers and polymerization and covers each major type of polymerization with relevant kinetics. The qualitative effect of reactor design on polymer manufacture is discussed as well as actual polymer manufacturing processes including those taking place in the UAE. Pre-requisites: CHEG / MEEG 380 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 CHEG397 CHEMICAL ENGINEERING INTERNSHIP The course requires students to complete a program of full time training to gain practical experience and apply their academic learning in an off-campus work or research environment. Pre-requisites: CHEG324 Co-requisites: None Restrictions: Students enrolled in CHEG397 cannot register for additional courses Lecture/Lab/Credit: 0:0:3 CHEG412 PROCESS DYNAMICS AND CONTROL Mathematical modeling and analysis of transient systems. Applications of control theory to response of dynamic chemical engineering systems and processes. Pre-requisites: CHEG212, CHEG324 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:3:4 CHEG415 COMBUSTION AND AIR POLLUTION CONTROL This course presents the fundamentals of air pollution impact on the environment. Topics covered include hydrocarbon fuel energy, the different combustion devices and systems, pollutant emission predictions from chemical equilibrium and ideal flow reactors, design of flues and chimneys, atmospheric dispersion models, air pollution sampling and measurement, and air pollution control methods and equipment. Applications in the petroleum industry are stressed. Pre-requisites: CHEG324 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 96 CHEG416 CORROSION ENGINEERING This course presents fundamental material on corrosion and oxidation thermodynamics and electrochemical thermodynamics. The course then describes commonly encountered corrosion environments and discusses typical forms of corrosion encountered in each environment typical to the petroleum industry. Methods of corrosion control are then described, and the course concludes with a description of important corrosion and oxidation monitoring techniques. Pre-requisites: CHEM 331 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 CHEG423 GAS PROCESSING ENGINEERING An overview of natural gas industry, from wellhead to market place. Process flow diagram of gas plant. Description and design of the major processes for gas compression, dehydration, acid gas removal and tail gas cleanup, sulfur recovery, cryogenic extraction of natural gas liquids (NGL). Process simulation of natural gas processes. Pre-requisites: CHEG332, CHEG324 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 2:3:3 CHEG424 PETROLEUM REFINING AND PROCESSING Characterization of crude oil. Petroleum products and refinery configuration. Basics on heterogeneous catalysis. Unit operations of petroleum refining including distillation, catalytic cracking, reforming, hydrotreating and hydrocracking, coking and gas treatment. Gasoline components. Refinery products and economics. Manufacture of petrochemical feedstocks from petroleum and petroleum products. Environmental control. Refinery safety measures and handling of hazardous materials. Quality control of products. Pre-requisites: CHEM212, CHEG324 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 CHEG440 SEPARATION PROCESSES This course addresses the basic principles of mass transfer to equilibrium and rate- controlled separation processes, in addition to modern separation techniques such as adsorption and membrane separation. Pre-requisites: CHEG324 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 97 CHEG443 REACTION ENGINEERING Applications of the fundamentals of thermodynamics, physical chemistry, and organic chemistry to the engineering of reactive processes. Reactor design; acquisition and analysis of rate data; heterogeneous catalysis. Relevant aspects of computer-aided process simulation. Pre-requisites: CHEM211, CHEG324 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:3:4 CHEG455 CHEMICAL ENGINEERING LABORATORY II This course is the second in a sequence of two courses that covers the laboratory work for the thermodynamics and the transport (fluid, heat, and mass) courses. The present course consists of laboratory experiments in heat and mass transfer. Students run experiments and analyze laboratory data using appropriate statistical methods, and produce oral and written technical reports. Pre-requisites: CHEG313, CHEG324 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 0:3:2 CHEG470 INDUSTRIAL CATALYSIS The course presents basic concepts of catalysis and briefly reviews different categories of catalysts with commercial importance for oil and gas processing as well as for petrochemical and other chemical commodities manufacturing. The core of the course is focused on heterogeneous catalysis and to a smaller extent to homogeneous catalysis. Catalytic materials, their properties and preparation, catalyst characterization and selection are presented with an emphasis on new synthesis and characterization methods. Several case studies of industrial processes are selected to offer an insight into the strong interaction among catalyst type, catalytic reactor design and process operating variables. The selected processes are analyzed in their evolution, limits and challenges and new technological solutions are suggested. Pre-requisites: CHEG443 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 CHEG472 WATER TREATMENT AND MEMBRANE PROCESSES This course deals with the fundamental principles and practical applications of membrane processes in water and wastewater treatment facilities. The topics covered in this course are water chemistry, membrane structure and performance, membrane transport, concentration polarization, membrane fouling and fouling characterization in relation to water and wastewater engineering. Applications of nano-filtration (NF), ultra-filtration (UF), micro- filtration (MF), reverse osmosis (RO) electro- dialysis, and pervaporation membranes in various water and wastewater treatment facilities will be discussed. Pre-requisites: CHEG324 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 98 CHEG488 POLYMER PROPERTIES Review and discussion of the properties of polymers with emphasis on structure-propertycorrelations. The principles and practical applications of the main techniques used for polymer characterization will be discussed. Some applications of polymers in relationship to their properties are illustrated. Pre-requisites: CHEG / MEEG 380 Co-requisites: None Restrictions:None Lecture/Lab/Credit: 3:0:3 CHEG490 CHEMICAL ENGINEERING DESIGN PROJECT I In this course, students study the design process including: problem definition and needs analysis; process synthesis, process debottlenecking and troubleshooting; safety and environmental protection in design; written and oral communication for design reports. A significant portion of the term work will be devoted to a group design project, culminating in a preliminary design proposal that will be presented to the department. Pre-requisites: CHEG313, CHEG314, CHEG324, STPS 251 Co-requisites: None Restrictions: Open to Chemical Engineering students only Lecture/Lab/Credit: 2:3:3 CHEG491 CHEMICAL ENGINEERING DESIGN PROJECT II A continuation of group design projects. Students continue studying the design process including equipment cost estimation, manufacturing cost, and profitability analysis, process optimization, material selection, energy, safety, and environmental considerations. A significant portion of the term work will be devoted to the group design project started in Design Project I, culminating in a final design report that will be Pre-requisitesCHEG490 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 CHEG293/393/493 SPECIAL TOPICS IN CHEMICAL ENGINEERING The course offers content not included in existing courses. A student can take multiple Special Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the Program Co-requisites: To be determined by the Program Restrictions: CHEG293 is open to Sophomore students and above, CHEG393 is open to Junior students and above, CHEG493 is open to Senior students only Lecture/Lab/Credit: 1-4 credits 99 CHEG394/494 RESEARCH TOPICS IN CHEMICAL ENGINEERING The course focuses on research-driven topics. A student can take multiple Research Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the Program Co-requisites: To be determined by the Program Restrictions: CHEG394 is open to Junior students and above, CHEG494 is open to Senior students only Lecture/Lab/Credit: 1-4 credits CHEG396/496 INDEPENDENT STUDY IN CHEMICAL ENGINEERING The course may offer content not included in existing courses in an independent study format based on a formal arrangement between the student and instructor. A student can take one or more Independent Study course (up to 6 credits). Independent Study courses require prior approval of the Department Chair and Provost (or designee). Pre-requisites: To be determined by the Program Co-requisites: To be determined by the Program Restrictions: CGPA 3.0, CHEG396 is open to Junior students and above, CHEG496 is open to Senior students only Lecture/Lab/Credit: 1-6 credits Chemistry (CHEM) CHEM 060 Introduction to Chemical Principles CHEM 060 is a developmental course that addresses essential skills needed for success in CHEM 101. CHEM 060 is an integrated chemistry course, comprised of three focus areas: chemical concepts, laboratory program, and study skills. The course provides an active learning experience designed to impart the fundamental concepts and principles of chemistry, with an emphasis on mathematics skills, logical thinking, and how to study/learn chemistry, both in and out of the classroom, and in the laboratory. Students required to enroll in this course are identified through their performance on the PI Chemistry placement test. Prerequisites: Entry into A&S program (TOEFL > 500) Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:3:4 (non-degree) CHEM 101 GENERAL CHEMISTRY I A study of the fundamental principles and laws of chemistry including stoichiometric relationships, aqueous chemistry, the ideal gas laws and kinetic molecular theory, thermochemistry, quantum theory and electronic structure, periodic properties, and chemical bonding and molecular structure. This course is accompanied by a laboratory component that emphasizes quantitative procedures. The combination of lecture and lab course is designed to meet the requirements of students majoring in any engineering program requiring a background in chemistry. Pre-requisites: TOEFL score of 500 or higher and either placement via Chemistry Placement Exam or credit for CHEM 060 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:3:4 100 CHEM 102 GENERAL CHEMISTRY II This course is a continuation of CHEM 101 and is designed to meet the requirements of students majoring in an engineering or science program that requires a strong background in chemistry. Topics include intermolecular forces, pure solids and liquids, properties of solutions, kinetics, equilibrium processes, chemical thermodynamics, and electrochemistry. This course is accompanied by a laboratory component that includes both quantitative and qualitative procedures. Pre-requisites: CHEM 101, MATH 111 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:3:4 CHEM 211 ORGANIC CHEMISTRY I This is the first course of a two-semester sequence introducing the fundamental principles of organic chemistry. Topics include structure, physical and chemical properties, reactions of several important functional classes, reaction mechanisms, and stereochemical considerations. Computational chemistry software is introduced as an aid to understanding the relationship between structure, properties, and chemical reactivity. This course is accompanied by a laboratory component which exposes students to a range of experimental techniques designed to purify organic compounds and to illustrate material in the lecture component. These techniques will be used in CHEM 212 in the following semester. Pre-requisites: CHEM 102 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:3:4 CHEM 212 ORGANIC CHEMISTRY II This course is a continuation of CHEM 211. It concentrates on the more advanced reactions of organic compounds and the reactions of some basic biomolecules. In addition, the course includes the analysis of detailed reaction mechanisms and the design of multistep chemical synthesis pathways. Mass spectrometry, infrared and NMR spectroscopy are also introduced to identify the structure of various organic compounds. This course is accompanied by a laboratory component in which students synthesize a range of organic compounds that they cover in the lecture component; such as aspirin, soap and banana ester. Overall, the course’s combination of lecture and lab is designed to meet the requests of the chemical engineering program. Pre-requisites: CHEM 211 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:3:4 101 CHEM 301 PHYSICAL CHEMISTRY This course includes topics in interfacial chemistry, adsorption, thermodynamics, aqueous solution equilibria, electrochemical kinetics and particulates. Colloidal systems including aerosol particles dispersed in gases, colloids in aqueous solutions, and fine liquid droplets are also covered. The application of these topics in chemical and petroleum engineering is described. The laboratory component exposes students to a range of experimental techniques designed to illustrate material in the lecture component. Pre-requisites: Chemistry 102 (General Chemistry II) and Math 261 (Differential Equations) Corequisites: None Restrictions: None Lecture/Lab/Credit: 3:3:4 CHEM 293/393/493 SPECIAL TOPICS IN CHEMISTRY The course offers content not included in existing courses. A student can take multiple Special Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the Department Co-requisites: To be determined by the Department Restrictions: CHEM 293 is open to Sophomore students and above, CHEM 393 is open to Junior students and above, CHEM 493 is open to Senior students only Lecture/Lab/Credit: 1-4 credits CHEM 394/494 RESEARCH TOPICS IN CHEMISTRY The course focuses on research-driven topics. A student can take multiple Research Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the Department Co-requisites: To be determined by the Department Restrictions: CHEM 394 is open to Junior students and above, CHEM 494 is open to Senior students only Lecture/Lab/Credit: 1-4 credits CHEM 396/496 INDEPENDENT STUDY IN CHEMISTRY The course may offer content not included in existing courses in an independent study format based on a formal arrangement between the student and instructor. A student can take one or more Independent Study course (up to 6 credits). Independent Study courses require prior approval of the Department Head and Provost (or designee). Pre-requisites: To be determined by the Department Co-requisites: To be determined by the Department Restrictions: CGPA 3.0, CHEM 396 is open to Junior students and above, CHEM 496 is open to Senior students only Lecture/Lab/Credit: 1-6 credits 102 Communication – (COMM) COMM 101, COMMUNICATION I Communication 101 (COMM 101) is designed to introduce students to the language and communication skills that are required for undergraduate study. Critical reading, critical writing and oral presentation skills are developed through a context of humanities and social science research projects which also aim to raise student awareness of quality time management skills and metacognition. Pre-requisites: TOEFL 500 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 4:0:4 COMM 151, COMMUNICATION II Communication 151 (COMM151) develops and builds on skills learned in COMM101 and focuses on the application of critical thinking and problem solving skills. Students are required to undertake a “real-world” academic, educational or technical project. Academic literacy, teamwork skills, project planning and time management skills are developed as students participate in seminars and work in teams to gather and share information, leading to individual graded assignments, extensive team-written project reports and multi-media research presentations. Pre-requisites: COMM101 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 4:0:4 Electrical Engineering (ELEG) ELEG 205 ELECTRIC CIRCUITS I Physical principles underlying the modeling of circuit elements. Basic circuit elements: resistance; inductance, capacitance, independent and controlled sources, and op-amps. Circuit analysis techniques, steady-state and transient responses, first-order circuits, complex numbers, sinusoidal steady-state analysis, sinusoidal steady-state power calculations, balanced threephase circuits. Pre-requisites: MATH 161 Co-requisites: PHYS 241 Restrictions: None Lecture/Lab/Credit: 3:3:4 ELEG 206 INTRODUCTION TO COMPUTER PROGRAMMING Overview of computer hardware and software, input/output, data types, variables, pseudocode, algorithms, control statements, operators, functions, arrays, strings, pointers, and file processing. Pre-requisites: MATH 111 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 2:3:3 103 ELEG 305 ELECTRIC CIRCUITS II Time-domain transient analysis, Laplace transform, s-domain circuit analysis, State variable circuit analysis, frequency selective circuits, first order passive filters, Bode diagrams, two-port networks, Mutual inductance and transformers. Pre-requisites: ELEG 205 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:3:4 ELEG 310 ENGINEERING ELECTROMAGNETICS Review of Vector analysis, Electrostatics (Electric fields, boundary value problem), Magneto statics (magneto static fields, magnetic force), Maxwell’s Equations, Plane Wave propagation, Transmission lines. Pre-requisites: ELEG 205 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 ELEG 315 SIGNALS AND SYSTEMS Interpretation, representation and analysis of time-varying phenomena (continuous or discrete) as signals that convey information; Analysis of linear systems using the convolution principle; the Fourier Series, the Fourier and its applications, the Laplace transform; the z-transform and its application; Sampling and signal reconstruction. Pre-requisites: ELEG 205, MATH 261 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 ELEG 325 ELECTRONIC DEVICES AND CIRCUITS Fundamentals of active semiconductor devices. The course focuses on building an understanding of junction diode, bipolar junction transistors, field-effect transistors devices, operational amplifiers, and special purposes ICs. A laboratory is integrated into the course; the focus of the laboratory is the study of semiconductor devices and circuits characteristics through simulation and experimental procedures. Pre-requisites: ELEG 205 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:3:4 ELEG 330 ELECTRIC MACHINES Magnetic circuit concepts and materials, transformer analysis and operation, steady state analysis of rotating machines. Study of the basic machine types: dc, induction, synchronous. A laboratory is integrated into the course; the focus of the laboratory is on the characteristics of machines and transformers. Pre-requisites: ELEG 205 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:3:4 104 ELEG 350 POWER SYSTEMS ANALYSIS Phasor diagrams; Real and Reactive power concepts; Elements of Power systems; Single line diagrams; Modeling of power system components; Per unit quantities; Load flow studies; Symmetrical components. Pre-requisites: ELEG 330 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 ELEG 360 FEEDBACK CONTROL SYSTEMS System modeling through an energy flow approach is presented, modeling of electrical, and mechanical systems are discussed. Feedback control design techniques using pole-placement, root locus, lead-lag, and PID compensators are presented and analyzed. Pre-requisites: ELEG 305 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:3:4 ELEG 380 LOGIC AND DIGITAL DESIGN Logic devices and circuits, Boolean algebra, analysis and synthesis of combinational and sequential logic systems, number representation. Introduction to VHDL. Pre-requisites: None Co-requisites: ELEG 205 Restrictions: None Lecture/Lab/Credit: 3:3:4 ELEG 385 MICROPROCESSORS AND CONTROLLERS This course provides a comprehensive understanding of the fundamentals of microprocessor/ microcontroller systems. Topics include architecture, data and instruction formats, addressing, interrupt processing and interfacing using assembly language programming. The microcontroller with its built-in processor along with its on-chip memory and its input/output capabilities are covered in detail. Design applications involving the interface and control of external devices by a microcontroller are implemented Pre-requisites: ELEG 380 and ELEG 206 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:3:4 ELEG 390 DATA COMMUNICATION This course discusses the concept of communication systems and networking at their different layers. Topics include various transmission media, modulation/demodulation (AM, FM, PM); signal coding techniques, error detection and corrections. The course also covers many real- world examples of data communication including wired and wireless Local Area Networks (LAN): topologies, Media Access Control (MAC), access techniques, and Wide Area Network (WAN): Introduction to internet protocols. Pre-requisites: ELEG 315 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 105 ELEG 397 ELECTRICAL ENGINEERING INTERNSHIP The course requires students to complete a program of full time training to gain practical experience and apply their academic learning in an off-campus work or research environment. Pre-requisites: Junior year in Electrical Engineering or permission of Program Chair Co-requisites: None Restrictions: Students enrolled in ELEG 397 cannot register for additional courses Lecture/Lab/Credit: 0:0:3 ELEG 410 FUNDAMENTALS OF POWER ELECTRONICS The course covers the basic of power semiconductor devices such as Thyristors, MOSFETs and IGBTs. The working principle and analysis of different circuit topologies of AC-DC, DC-AC, ACAC and DC-Dc converters are introduced. Mathematical modeling of these circuits is introduced. Gate circuit design and concept of zero voltage and zero current switching is introduced. Applications of power electronic systems and their effect ton power system are discussed. Pre-requisites: ELEG 325, ELEG 330 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 ELEG 420 MODERN CONTROL SYSTEMS Design of modern control systems using matrix approach and the linear systems tools in MATLAB; examples from electrical and mechanical engineering; realization techniques; discretization of continuous systems; controllability, observability and their Gramians, other dynamical system properties; pole- placement; disturbance rejection; Lyapunov stability; state estimation; introduction to multivariable systems; introduction to intelligent control systems. Pre-requisites: ELEG 360 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 ELEG 440 INSTRUMENTATION AND MEASUREMENT Introduction to measurement systems, sensors and transducers, data acquisition and analysis, signal conditioning, instrumentation methods, system specifications, computer interfacing, noise concerns and ergonomic aspects. Pre-requisites: ELEG 325 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:3:4 106 ELEG 450 ELECTRIC POWER DISTRIBUTION SYSTEMS The course covers electric power distribution network architecture and composition including Load curves, Substations, Industrial networks, Distribution voltage and power control, Distribution system planning and design, Distribution system losses, Distribution transformer applications, Pole-top and pad-mounted distribution transformers, Unbalance voltage and unsymmetrical loading. Pre-requisites: ELEG 350 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 ELEG 458 ELECTRIC POWER QUALITY Introduction and analysis of power quality and harmonics phenomena in electric power systems: characteristics and definitions, voltage sags, electrical transients, harmonics, mitigation techniques, electromagnetic interference, grounding electrical equipment, and standards of power quality. Pre-requisites: ELEG 350 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 ELEG 460 DIGITAL SIGNAL PROCESSING This combined theory and practical course introduces the principles of digital signal processing (DSP). The course begins with an introduction to discrete-time signals and systems followed by such topics as sampling, A/D conversion, aliasing, the z-transform, discrete & fast Fourier transform and digital filter design. Pre-requisites: ELEG 315 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 ELEG 465 INDUSTRIAL AUTOMATION Principles of industrial automation with emphasis on oil and gas industries. Topics on sensors, actuators, field devices, signal conditioning, PLCs, and ladder logic programming are covered in theory and practice. Different types of closed loop controllers, system modeling, SCADA, and DCS are also addressed. Pre-requisites: ELEG 440 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:3:4 107 ELEG 470 ADVANCED POWER ELECTRONICS A study of high-frequency switching circuits which convert and condition electrical power. Topics covered are linear & switching DC power supplies, inverters, dc-dc converters and powerfactor correction converters. This course provides the fundamental knowledge of pulse- width modulated converter circuits, modelling and design of their feedback systems, current- mode control, simulation, input EMI filter design, modelling and design of high-frequency power magnetic elements and low-harmonic rectifiers. Design- oriented analysis is always emphasized. Pre-requisites: ELEG 410 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 ELEG 475 POWER SYSTEMS PROTECTION AND RELAYS The course is about the principles behind the protection of electric systems and covers the role of relaying theory, Relaying Fundamentals, Transducers, Transient Phenomena, DC offset in fault currents, Distribution System Protection, Sub-transmission System Protection, Response of Distance Relays, Pilot Line Protection, Transformer Protection and Rotating Machinery Protection. Pre-requisites: ELEG 350 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 ELEG 480 DIGITAL CONTROL SYSTEMS This course is concerned with the analysis and design of closed-loop systems that contain a digital computer. Distinction is emphasized between a purely digital system and a continuous system that may be sampled to emulate a digital system. Topics covered include sampling, signal conversion and processing (hold devices; z-transform; state variable technique; pole- assignment and state estimation; stability of digital control systems; digital simulation and redesign; time and frequency domain analyses; digital filter structures and microcomputer implementation of digital filters. Pre-requisites: ELEG360 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 ELEG 490 ELECTRICAL ENGINEERING DESIGN PROJECT I Capstone Design. Project engineering techniques and professional practice issues. Design methods and tools, product life cycle, standards, project management, legal and ethical issues in engineering. Pre-requisites: Senior year standing or permission of Program Chair Co-requisites: None Restrictions: Open to Electrical Engineering students only Lecture/Lab/Credit: 1:3:2 108 ELEG 491 ELECTRICAL ENGINEERING DESIGN PROJECT II Project engineering techniques and professional practice issues. Design methods and tools, product life cycle, standards, project management, legal and ethical issues in engineering, hardware implementation of design project. Pre-requisites: ELEG 490 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 1:6:3 ELEG 293/393/493 SPECIAL TOPICS IN ELECTRICAL ENGINEERING The course offers content not included in existing courses. A student can take multiple Special Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the Program Co-requisites: To be determined by the Program Restrictions: ELEG 293 is open to Sophomore students and above, ELEG 393 is open to Junior students and above, ELEG 493 is open to Senior students only Lecture/Lab/Credit: 1-4 credits ELEG 394/494 RESEARCH TOPICS IN ELECTRICAL ENGINEERING The course focuses on research-driven topics. A student can take multiple Research Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the Program Co-requisites: To be determined by the Program Restrictions: ELEG 394 is open to Junior students and above, ELEG 494 is open to Senior students only Lecture/Lab/Credit: 1-4 credits ELEG 396/496 INDEPENDENT STUDY IN ELECTRICAL ENGINEERING The course may offer content not included in existing courses in an independent study format based on a formal arrangement between the student and instructor. A student can take one or more Independent Study course (up to 6 credits). Independent Study courses require prior approval of the Program Chair and Provost (or designee). Pre-requisites: To be determined by the Program Co-requisites: To be determined by the Program Restrictions: CGPA 3.0, ELEG 396 is open to Junior students and above, ELEG 496 is open to Senior students only Lecture/Lab/Credit: 1-6 credits 109 Engineering (ENGR) ENGR 101 INTRODUCTION TO ENGINEERING IN THE PETROLEUM INDUSTRY ENGR 101 This course enables students to gain an understanding of the petroleum industry, the role of engineers in this industry, the pathway to academic success in engineering studies, and membership into a learning community. Knowledge and skills gained will be applied by students to improve their performance in their engineering studies and in determining their choice of major. The development of the desired knowledge, skills and positive attitudes will occur through a series of student-centered activities, field trips, and guest speakers from industry, including PI alumni. All of these activities are linked through the themes of exploring, producing, transporting, refining, processing, contributing and marketing. The course is at the center of establishing a structured learning community, a core aspect of the First Year Experience. Pre-requisites: Freshman year standing Co-requisites: None Restrictions: None Lecture/Lab/Credit: 2:3:3 ENGR 201 STATICS Forces, moments, couples, equilibrium of bodies in two and three-dimensions, centroids and second moments of areas, volumes and masses, friction and virtual work. Pre-requisites: PHYS191 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 ENGR 293/393/493 SPECIAL TOPICS IN ENGINEERING The course offers content not included in existing courses. A student can take multiple Special Topics courseswith different content for credit subject to program approval. Pre-requisites: To be determined by the Department Co-requisites: To be determined by the Department Restrictions: ENGR 293 is open to Sophomore students and above, ENGR 393 is open to Junior students and above, ENGR 493 is open to Senior students only Lecture/Lab/Credit: 1-4 credits ENGR 394/494 RESEARCH TOPICS IN ENGINEERING The course focuses on research-driven topics. A student can take multiple Research Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the Department Co-requisites: To be determined by the Department Restrictions: ENGR 394 is open to Junior students and above, ENGR 494 is open to Senior students only Lecture/Lab/Credit: 1-4 credits 110 ENGR 396/496 INDEPENDENT STUDY IN ENGINEERING The course may offer content not included in existing courses in an independent study format based on a formal arrangement between the student and instructor. A student can take one or more Independent Study courses (up to 6 credits). Independent Study courses require prior approval of the Department Head and Provost (or designee). Pre-requisites: To be determined by the Department Co-requisites: To be determined by the Department Restrictions: CGPA: 3.0, ENGR 396 is open to Junior students and above, ENGR 496 is open to Senior students only Lecture/Lab/Credit: 1-6 credits ENGR 469 TECHNOLOGY DEVELOPMENT VENTURES AND ENTREPRENEURSHIP This course is designed to help students learn the basic business, strategy, and leadership skills needed to launch new technology-oriented ventures. Topics include learning how to assess the feasibility of a technological innovation as well as how to apply best practices for planning, launching, and managing new technology-oriented companies. Students will participate in team projects and case studies which will include feasibility studies, writing and presenting business plans, and presentations for investors. Pre-requisites: Senior Standing or Permission of Instructor Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 ENGR 498 PROFESSIONAL EXAMINATION PREPARATION The course reviews and reinforces knowledge of engineering and science principles, and assists students with successfully completing the “Fundamentals of Engineering Examination” administered by the National Council of Examiners for Engineering and Surveying (NCEES) or similar professional examinations. Pre-requisites: Senior year standing Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:2 111 Health & Fitness (HFIT) HFIT 111 Personal Health and Fitness An overview of personal health and fitness, with particular relevance to working in the petroleum and gas industries. The course includes a theoretical and practical understanding of personal health and fitness including exercising safely and managing a personal healthy diet and managing a healthy diet and lifestyle regime. The course is enhanced with opportunities for field work, personal survival techniques and the fundamental skills of leadership and teamwork. Pre-requisites: None Co-requisites: None Restrictions: None Lecture/Lab/Crdit: 0.5/1.5/1 STPS 201 Strategies for Team Based Engineering Problem Solving I STPS201 introduces the engineering design process including problem definition, conceptual design, alternative solutions and final design specifications and documentation. Students in teams work on open-ended problems and apply the formal methods of engineering design. The course also develops and enhances team work, project management and professional design communications including technical writing, graphics communication and effective oral presentations. Issues such as social and environmental aspects of engineering design and engineering ethics are also addressed. Pre-requisite: COMM 151, ENGR 101 Co-requisite: PHYS 191 Restrictions: None Lecture/Lab/Credit: 2:3:3 STPS 251 Strategies for Team-Based Engineering Problem Solving II This course is a development of STPS 201 emphasizing application of learned professional sills. Team-based engineering problem solving with emphasis on discipline specific client-based problems. There is an increased focus on discipline specific computer applications in design, engineering principles and practices to solve open-ended problems. Oral and written professional technical communications as well as teamwork and project management are further developed. Human, environmental and economical aspects of engineering design are also addressed. Pre-requisite: STPS 201 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 2:3:3 112 Health, Safety and Environment Engineering (HSEG) HSEG 401INTRODUCTION TO HSE ENGINEERING Concepts of workplace health, safety and environment (HSE) will be discussed as they relate to the oil, gas, petrochemical and associated industries. Students will develop an understanding of how businesses manage HSE and the regulatory responsibilities, and be able to prepare for further study in the field. Included is a historical perspective of the legislative process of regulations, explanation of HSE terms, ethics and professionalism, recordkeeping and HSE statistics, hazard recognition / evaluation / control, accident investigation and analysis, emergency preparedness, security, workers’ compensation, concepts of pollution control, waste management, and HSE management systems. Pre-requisites: Junior/Senior standing or permission of the program chair. Not open to students who have completed PEEG 359. Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 HSEG 402 INDUSTRIAL HYGIENE ENGINEERING This course studies the anticipation, recognition, evaluation, and control issues associated with industrial health and hygiene in the workplace. Topics include toxicology, epidemiology, noise, ionizing and non- ionizing radiation, chemicals, airborne contaminants, biological substances and sampling techniques. These subjects will be discussed in relation to regulatory requirements using engineering and non- engineering controls for reducing or eliminating health hazards in the workplace. Pre-requisites: Junior/Senior standing or permission of the program chair. Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 HSEG 405 SYSTEM SAFETY ENGINEERING AND RISK MANAGEMENT This course focuses on the evaluation of system design and process safety from the standpoint of risk, using system safety analysis techniques. Topics covered include concept of risk, system definition, hazard identification, risk assessment, risk management, sensitivity analysis and economics of system safety methodology, mathematics of systems analysis including statistical methods, Boolean algebra and reliability. Skills gained include the ability to calibrate a risk assessment matrix, perform preliminary hazard analysis (PHA), failure mode and effect analysis (FMECA), fault tree analysis (FTA), job safety analysis, event trees, task analysis, process flow analysis, HAZOP (hazard and operability) analysis, and other system safety analysis techniques. Pre-requisites: Junior/Senior standing or permission of the program chair. Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 113 HSEG 411 ERGONOMICS AND HUMAN FACTORS ENGINEERING This course studies human performance and its effect on the safety and reliability of systems. Information about human abilities, limitations and other characteristics will be used to design jobs, equipment, work methods and environmental conditions that will optimize human productivity in occupational settings. Engineering anthropometry, human information processing, biomechanics of motion and work posture, work physiology and human performance, thermal conditions (heat stress), the human visual system, vibration, illumination and indoor air quality, are covered in context of their application and workplace design. Pre-requisites: Junior/Senior standing or permission of the program chair. Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 Humanities and Social Sciences (H&SS) H&SS 111 ISLAMIC STUDIES This course explores the meaning of the traditional values and ethics of Islam and their significance in today’s modern, scientific, and technological world. It includes a brief survey of Islamic ethics across the history of Islam. The course highlights the application of Islamic ethical values within three major spheres: the social setting, the workplace and the environment. Based on the Sunnah and the historical record of Islam, emphasis is placed on how Islamic ethics can contribute to issues facing modern society in meeting the challenges of the working environment and in raising an ecological consciousness of a modern, global society in its relationship with the natural environment. Pre-requisites: None Co-requisites: COMM 151 Restrictions: None Lecture/Lab/Credit: 3:0:3 H&SS 112 ARABIC LANGUAGE The course is designed to improve students’ proficiency in the reading and writing of academic and scholarly Arabic. Students will be taught to read, write and speak classical Arabic. They will also be introduced to notable classical and modern texts as they pertain to various aspects of social life. Topics to be covered include letters, Arabic and Islamic texts, and texts of prominent Arab writers. Students with an advanced understanding of classical Arabic will further develop their reading and writing skills while those with a more rudimentary understanding will derive remedial benefit from the course. Pre-requisites: None Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 114 H&SS 121 GERMAN LANGUAGE I German I is designed for students interested in learning the German language. Initial focus is on conversational German to allow the student to function in a German speaking setting. Elementary grammar and written construction are introduced. Pre-requisites: Permission of instructor Co-requisites: None Restrictions: Any previous secondary or post-secondary course in German Lecture/Lab/Credit: 3:0:3 H&SS 171 GERMAN LANGUAGE II In this course, students understand and make up short simple questions, directions and messages in various situations including public announcements and short conversations at a higher level. Students’ skills in writing, reading, speaking and listening are improved so that they can take part in an extended preparation course of the official examination START 1 of the German GoetheInstitute at the end of this course. Pre-requisites: H&SS 121 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 H&SS 200 INTRODUCTION TO BUSINESS MANAGEMENT The course provides a basic introduction to contemporary business environments and the responsibilities of management in an organization. It analyses operations of core functions of firms such as marketing, R&D, sales, operations, human resources, and also examines the theoretical and applied evolution of managerial functions of planning and decision making, organizing and changing, leading and controlling. Pre-requisites: COMM 151 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 H&SS 201 THE WEST IN THE MIDDLE EAST This course examines the presence of the West in the Middle East over the past thousand years. Its starting point is the Crusades, and it goes on to consider the impact of European commercial activity in the seventeenth and eighteenth century. European colonialism in the region during the nineteenth and twentieth century, and the effects of World War I upon the subsequent stages. The course includes an examination of the discovery and exploitation of the Middle East’s oil reserves, and the geopolitics that accompanied the development. Pre-requisites: COMM 151 Co-requisites: None Restrictions: None Lecture/Lab/Credit:3:0:3 115 H&SS 221 INTRODUCTION TO POLITICAL SCIENCE This course introduces the fundamental principles of comparative government, political theory, international and public policy, and their application in the Islamic societies of the Arabian Gulf and the oil and gas industry. Pre-requisites: COMM 151 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 H&SS 222 THE UAE BEFORE AND SINCE THE DISCOVERY OF OIL This course examines the special relationship between the Gulf sheikhdoms and Britain from 1820 until 1971, and the UAE in the oil era. Pre-requisites: COMM 151 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 H&SS 251 PRINCIPLES OF ECONOMICS This course is designed to provide students the basic set of tools that are necessary to analyse economics and business problems. The course is divided into four main sections. The first section introduces the student to the economic way of thinking and some core economic principles. The second part develops and then applies the supply and demand model to various microeconomic situations including discussions regarding the role of the government. Section three studies the producer theory and market structures. The final section examines the aggregate view of the economy including GDP, employment, inflation, exchange rates, and government macroeconomic policies. Pre-requisites: COMM 151 or AP English Co-requisites: MATH 111 Restrictions: None Lecture/Lab/Credit: 3:0:3 H&SS 253 TOPICS IN QURANIC & HADITH STUDIES This course includes special topics in Islamic studies, history, and culture. It offers a survey on a variety of selected topics which include religious traditions in both the classical and modern periods. Specific topics include the Qur’an the Hadith’ the life of the Prophet Muhammed (PBUH), religious history, Quranic interpretation, the sacred law and the finance. The course investigates how Muslims of different sorts, and in different times and places, have understood and constructed Islam in particular ways. Pre-requisites: COMM 151 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 116 H&SS 261 ENGINEERING ETHICS FROM AN ISLAMIC PERSPECTIVE The course introduces moral principles within the scope of engineering education and includes the following topics: professional and ethical responsibility; identifying, formulating, and resolving the moral issues raised by engineering practice; and understanding the impact of engineering solutions in a global and societal context. Different codes of engineering ethics such as NSPE and IEEE are emphasized, as is an Islamic code of ethics and the role an engineer should play in their community. Different models of professionalism are also analyzed in connection with moral obligations from an Islamic perspective. Pre-requisites: COMM 151 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 H&SS 321 THE POLITICAL ECONOMY OF JAPAN Provides a broad introduction to Japan including its importance as a major economic partner of the U.A.E. Topics covered include history, politics, economics, society and technology. Pre-requisites: COMM 151 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 H&SS 333 THE HISTORY AND POLITICS OF MIDDLE EAST OIL This course provides a survey of the oil industry in the region from the early 1900’s to the present day. Amongst the aspects studied are relationships between rulers and oil companies, the types of concessions agreed, problems and conflicts associated with oil developments, imperialism and oil, oil and the two world wars, nationalism and oil, the establishment of OPEC and OAPEC and finally the story of oil in the UAE. Pre-requisites: COMM 151 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 H&SS 381 MACROECONOMICS – THE UAE ECONOMY The course is designed to provide students with sound understanding of the UAE economy and other national economies. The aims of the course are: (i) to provide a deeper knowledge of the principles of macroeconomic analysis, (ii) use these principles to understand the macroeconomic dimensions of UAE economic history and in a broader international context, and (iii) develop good understanding of the general working of the economy to make sense of governmental policy-making and changes occurring in the world economy today. The course blends in facts and data about other economies to explore contemporary issues in more depth. Prerequisites: H&SS 251 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 117 H&SS 293/393/493 SPECIAL TOPICS IN HUMANITIES AND SOCIAL SCIENCES The course offers content not included in existing courses. A student can take multiple Special Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the Department Co-requisites: To be determined by the Department Restrictions: H&SS 293 is open to Sophomore students and above, H&SS 393 is open to Junior students and above, H&SS 493 is open to Senior students only Lecture/Lab/Credit: 1-4 credits H&SS 394/494 RESEARCH TOPICS IN HUMANITIES AND SOCIAL SCIENCES The course focuses on research-driven topics. A student can take multiple Research Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the Department Co-requisites: To be determined by the Department Restrictions: H&SS 394 is open to Junior students and above, H&SS 494 is open to Senior students only Lecture/Lab/Credit: 1-4 credits H&SS 396/496 INDEPENDENT STUDY IN HUMANITIES AND SOCIAL SCIENCES The course may offer content not included in existing courses in an independent study format based on a formal arrangement between the student and instructor. A student can take one or more Independent Study course (up to 6 credits). Independent Study courses require prior approval of the Department Head and Provost (or designee). Pre-requisites: To be determined by the Department Co-requisites: To be determined by the Department Restrictions: CGPA:3.0, H&SS 396 is open to Junior students and Senior students only Lecture/Lab/Credit: 1-6 credits above, H&SS 496 is open to Mathematics (MATH) MATH 060 COLLEGE MATHEMATICS MATH 060 is a developmental course that addresses essential skills and knowledge needed for success in MATH 111. In this course, elementary concepts are introduced, related to new material, and revisited in an integrated approach. The basics of algebraic manipulation, trigonometry, logarithms, and the interpretation for graphs of functions are covered. Students required to enroll in this course are identified through their performance on the PI Mathematics placement test. Pre-requisites: Entry into A&S Program (TOEFL 500 or higher) 118 MATH 111 CALCULUS I This is the first course in the three-part Calculus sequence. The course explores the concepts of a limit, continuity and differentiation. The concepts are used to solve problems such as optimization, graphing, related rates, and motion. The concepts of integration are introduced and applied to the calculation of areas, volumes, arc length and work. Pre-requisites: TOEFL 500 or higher and either placement via Mathematics Placement Exam or credit for MATH 060 Co-requisites: None Restrictions: None Lacture/Lab/Credit: 4:0:4 MATH 161 CALCULUS II A second course in calculus covering some techniques of integration, sequences and series, vectors in both two and three dimensions, planes and surfaces, curves and arc length, and vectorvalued functions with their derivatives and integrals. Applications of the material to a number of physical situations relevant to both science and engineering are made. Pre-requisites:MATH111 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 4:0:4 MATH 212 CALCULUS III A third course in calculus covering differential and integral calculus of functions of several variables, including partial derivatives, maximum/minimum problems, double and triple integrals in various coordinate systems, line integrals, surface integrals, Greens Theorem, Stokes, Theorem, and the Divergence Theorem. Applications of the mathematics to a number of physical situations important to both science and engineering will be made. Pre-requisites: MATH 161 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MATH 241 PROBABILITY AND STATISTICS FOR ENGINEERS This course is an introduction to probability and statistics for engineers. Topics include data analysis, probability, random variables, discrete and continuous probability distributions, estimation, hypothesis testing and correlation. Students will have some experience in analyzing data using Minitab. Pre-requisites: MATH 212 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 119 MATH 261 DIFFERENTIAL EQUATIONS This course treats basic theory and standard methods of solution for elementary ordinary differential equations with applications. Pre-requisites: MATH 212 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MATH 361 ADVANCED ENGINEERING MATHEMATICS This course treats the classical partial differential equations of mathematical physics. Fourier series, transforms, and integrals are covered, as are topics from complex numbers and special functions. Pre-requisites: MATH 261 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MATH 365 NUMERICAL METHODS This is a first course in numerical and approximation techniques designed for undergraduate engineering students. The course covers root finding techniques for solving non-linear equations, numerical solution of systems of linear and non-linear equations, interpolation and approximation of functions or tabulated data, least square approximation, numerical integration using quadrature rules, numerical solution of ordinary differential equations and an introduction to error analysis. The student will also learn to write programs implementing these methods. Pre-requisites: MATH 261 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MATH 371 OPERATIONS RESEARCH FOR ENGINEERS This course covers linear programming (LP) problems and solutions by the Simplex method including blending, production processes, inventory, scheduling, assignment and transportation problems. In this course the student will learn to set up a model and solve the model problem both analytically and using software such as Lindo and Lingo. Pre-requisites: MATH 161 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MATH 461 LINEAR ALGEBRA This is an introductory course in linear algebra. Topics covered in this course include systems of linear equations, matrix algebra, determinants, vector spaces, subspaces, linear independence, span, basis, coordinates, linear transformations, matrix representations of linear transformations, eigenvalues and eigenvectors, diagonalization, Gram-Schmidt orthogonalization, orthogonal projection and least squares. Pre-requisites: MATH 212, ELEG 206 or MEEG 221 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 120 MATH 293/393/493 SPECIAL TOPICS IN MATHEMATICS The course offers content not included in existing courses. A student can take multiple Special Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the Department Co-requisites: To be determined by the Department Restrictions: MATH 293 is open to Sophomore students and above, MATH 393 is open to Junior students and above, MATH 493 is open to Senior students only Lecture/Lab/Credit: 1-4 credits MATH 394/494 RESEARCH TOPICS IN MATHEMATICS The course focuses on research-driven topics. A student can take multiple Research Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the Department Co-requisites: To be determined by the Department Restrictions: MATH 394 is open to Junior students and above, MATH 494 is open to Senior students only Lecture/Lab/Credit: 1-4 credits MATH 396/496 INDEPENDENT STUDY IN MATHEMATICS The course may offer content not included in existing courses in an independent study format based on a formal arrangement between the student and instructor. A student can take one or more Independent Study course (up to 6 credits). Independent Study courses require prior approval of the Department Head and Provost (or designee). Pre-requisites: To be determined by the Department Co-requisites: To be determined by the Department Restrictions: CGPA:3.0, MATH 396 is open to Junior students and above, MATH 496 is open to Senior students only Lecture/Lab/Credit: 1-6 credits Mechanical Engineering (MEEG) MEEG 201 ENGINEERING STATICS This course introduces the concept of force and moment equilibrium of solid bodies in two and three dimensions. Newton’s fundamental laws and principles of geometric properties of solids are covered. Free body diagrams and methods of joints and sections are used to analyze structures. Construction of internal shear force and bending moment diagrams in beams are introduced. Pre-requisites: PHYS 191 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 121 MEEG 205 INTRODUCTION TO MODERN MECHANICAL ENGINEERING This course introduces the students to modern mechanical engineering as a profession and discipline. The mechanical engineering curriculum is reviewed. Topics of current interest and emerging areas in modern mechanical engineering are introduced, including topics related to the oil and gas and the broader energy sector. The role of codes and standards is introduced. Professional engineering ethics and responsibility are presented. Knowledge in modern mechanical engineering is also gained through invited lectures, class discussions and field trip(s)/project(s). Pre-requisites: None Co-requisites: None Restrictions: None Lecture/Lab/Credit: 2:0:2 MEEG 221 ENGINEERING MATLAB This course develops the skills to use MATLAB as a tool to obtain numerical solutions to a wide range of engineering problems and display the results with annotated graphics. Students will also learn fundamentals of structural programming and numerical analysis techniques. Pre-requisites: MATH 212 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MEEG 222 INTRODUCTION TO ENGINEERING THERMODYNAMICS This course introduces the first and second laws of thermodynamics, properties of pure substances, entropy, reversible and irreversible processes. Pre-requisites: CHEM 102 Co-requisites: None Restrictions: Not open to Chemical and Mechanical Engineering students Lecture/Lab/Credit: 3:0:3 MEEG 275 BASIC MEASUREMENT LABORATORY This course provides an introduction to the science of metrology and measurements in mechanical engineering. Students communicate their work through oral presentations and written reports. Pre-requisites: PHYS 191, COMM 151 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 1:3:2 MEEG 302 FLUID MECHANICS AND HEAT TRANSFER This course covers fluid properties, statics, conservation of mass and energy, viscous laminar and turbulent flow in a pipe, boundary layer concept, flow over immersed bodies, steady and unsteady conduction, internal and external forced and natural convection heat transfer, radiation heat transfer, and heat exchangers. Pre-requisites: MEEG 222 Co-requisites: None Restrictions: Not open to Chemical and Mechanical Engineering students Lecture/Lab/Credit: 3:0:3 122 MEEG 324 ENGINEERING DYNAMICS This course introduces rectilinear and curvilinear motion of particles and rigid bodies, kinematics and kinetics of particles and rigid bodies, rotational and translational motion of rigid bodies, principle of work and energy in particles and rigid body dynamics, and principle of impulse and momentum in particle and rigid body dynamics. Pre-requisites: MEEG 201 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MEEG 334 MATERIALS SCIENCE This course introduces the three primary groups of engineering materials and the relationship between the structural elements of these materials and their properties. Atomic structure and inter-atomic bonding in metals, ceramics and polymers and discussed. Imperfections in crystal structure, diffusion, phase transformations and microstructure are studied in relationship to material properties such as tensile strength, hardness, fatigue and creep. Some of the fundamental concepts are further supported by laboratory experiments. Pre-requisites: CHEM 101 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:3:4 MEEG 344 MECHANICS OF MATERIALS This course introduces the concepts of stress, strain and Hooke’s law to study the mechanics of deformable solids. Axial loading, torsion, pure bending, analysis and design of beams for strength and deflection are covered. Shearing stress in beams and thin-walled sections, compound stresses, stress transformation, pressure vessels, and columns are introduced. Pre-requisites: MEEG 201 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MEEG 345 INTRODUCTION TO MANUFACTURING PROCESSES This course introduces the basic manufacturing processes and the interrelations between material properties, processes and design. Casting, bulk forming, sheet metal forming, material removal and joining processes and their applications to metals, polymers and composites are covered. The effects of processing on microstructure and strength are discussed. Hands on laboratory sessions emphasize some of the concepts covered in the lectures. Pre-requisites: None Co-requisites: None Restrictions: None Lecture/Lab/Credit: 2:3:3 123 MEEG 354 FLUID MECHANICS This course covers fluid properties, statics, conservation of mass, momentum and energy, dimensional analysis and similitude, viscous laminar and turbulent flow in a pipe, boundary layer concept, and flow over immersed bodies. Pre-requisites: MEEG 201, MEEG 365 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MEEG 365 THERMODYNAMICS This course introduces the first and second laws of thermodynamics, properties of pure substances, entropy, reversible and irreversible processes, power and refrigeration cycles and heat pump. Pre-requisites: PHYS 191, CHEM 101 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 4:0:4 MEEG 374 MACHINE DESIGN This course introduces the fundamentals of design and basic operation of various machine elements. Principles of statics and mechanics of materials are applied and failure theories are introduced for the design and selection of machine elements such as shafts, flexural members, power screws, fasteners, and welded joints. Pre-requisites: MEEG 344 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MEEG 376 CORE MEASUREMENTS LABORATORY This course builds upon fundamental concepts and principles introduced in MEEG 275 and offers experiments in the major specialty areas of thermofluids, mechanics, automation and control. Students also design hands-on experiments to investigate fundamental engineering phenomena through Design of Experiments (DOE). Students communicate their work through oral presentations and written reports. Pre-requisites: MEEG 275, MEEG 345 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 1:3:2 MEEG 380 INTRODUCTION TO POLYMER SCIENCE AND ENGINEERING This course introduces fundamentals, properties and applications of polymers. Classification of polymers, polymer formation, polymer structure, characterization, and the relationship between structure and properties are covered. Mechanical properties of polymers are discussed in relationship to their application as engineering materials. The influence of the various stages of polymer processing on properties of the end product is emphasized. Pre-requisites: CHEM 101, PHYS 191 Co-requisites: None Lecture/Lab/Credit: 3:0:3 124 MEEG 384 SYSTEM DYNAMICS AND CONTROL This course introduces modeling of mechanical, electrical and electromechanical systems, Laplace Transform techniques, time response analysis, block diagram representation, feedback systems, root locus method, frequency response techniques, state-space representation, and controller design. Pre-requisites: MATH 261, MEEG 221, MEEG 324, ELEG 205 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MEEG 385 HEAT TRANSFER This course covers the fundamental concepts of steady and unsteady conduction, internal and external forced and natural convection and radiation heat transfer, and heat exchanges. Pre-requisites: MEEG 354, MATH 261 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MEEG 397 MECHANICAL ENGINEERING INTERNSHIP Students are assigned to a variety of ADNOC’s operating companies where they will work on short-duration projects allowing them to apply the acquired knowledge from the PI, gain practical experience and become acquainted with the industry’s working environment. Each student is required to submit a written report and deliver a presentation on his work assignment. Pre-requisites: Senior standing in MEEG Co-requisites: None Restrictions: Students enrolled in MEEG 397 cannot register for additional courses Lecture/Lab/Credit: 0:0:3 MEEG 404 INTRODUCTION TO FINITE ELEMENT ANALYSIS This course introduces fundamental concepts of the finite element method. The derivation of spring, truss, beam, and frame element stiffness equations are covered and the direct stiffness method is used to analyze structures. Engineering examples in 2D and 3D are analyzed with the aid of finite element software and various modeling techniques are introduced. Pre-requisites: MEEG 221, MEEG 344 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MEEG 410 VISCOUS AND BOUNDARY LAYER FLOWS This course covers differential analysis of viscous fluid flow, exact solutions of the Navier-Stokes equations, laminar and turbulent boundary layers, Blasius and Von Karman integral solutions, the Polhausen method, and flow separation. Pre-requisites: MEEG 354 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 125 MEEG 424 GAS DYNAMICS This course covers one dimensional compressible gas flows and application to nozzles, compressible flow with friction and heat transfer (Fanno and Rayleigh Flows), and shock waves. Pre-requisites: MEEG 354 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MEEG 436 FRACTURE AND FAILURE OF ENGINEERING MATERIALS The course introduces the theories of various fracture mechanisms and fracture modes associated with failure of engineering materials. Concept of linear elastic fracture mechanics, stress intensity factor, Griffith energy balance, determination of the elastic field at a sharp crack tip, J integrals analysis, experimental determination of fracture toughness, elastic plastic fracture mechanics, fatigue crack growth, elastic-plastic crack tip fields, critical crack sizes and fatigue crack propagation rate prediction are covered. Pre-requisites: MEEG 334, MEEG 374 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MEEG 439 MACHINE DYNAMICS This course introduces fundamentals of kinematics of linkages, cams, gears and gear trains. It also covers position, velocity, and acceleration analysis of machines, static and dynamic force analysis of mechanisms. Pre-requisites: MEEG 221, MEEG 324 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MEEG 444 ENGINEERING VIBRATION This course introduces the theory of mechanical vibrations including free and forced vibrations of single and multiple degree of freedom systems, damping, matrix methods, time domain and frequency domain analysis, instrumentation, and vibration control. Pre-requisites: MEEG 384 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MEEG 454 REFRIGERATION, AIR CONDITIONING AND CRYOGENICS This course covers psychometrics, air conditioning systems, advanced refrigeration cycles, heating and cooling loads, and principles of cryogenics. Pre-requisites: MEEG 385 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 126 MEEG 459 TURBOMACHINERY This course covers the fundamentals of turbo machines analyses, velocity triangle method, performance characteristics, applications and selection of turbo machines for a variety of engineering situations such as pumping, gas compression and power production. Pre-requisites: MEEG 354 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MEEG 479 ENGINEERING PROJECT MANAGEMENT The course involves systematic approach to engineering project management with topics in project planning, scheduling, quality/cost control, intellectual/proprietary property management, communication management with the executives, work ethics, and health/safety/environmental aspects of project management. Pre-requisites: Completion of 90 credits and good academic standing Co-requisites: None Restrictions: CGPA:2.0 Lecture/Lab/Credit: 3:0:3 MEEG 480 RENEWABLE ENERGY TECHNOLOGIES This course covers the primary conventional and renewable energy sources such as solar, wind, biomass, hydro-electric, ocean, geothermal, and energy applications in various energy sectors. It also discusses the environmental and cost aspects of these energy sources. Pre-requisites: MEEG 365 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 MEEG 485 INTRODUCTION TO ROBOTICS This course introduces fundamentals of robotics including kinematics, dynamics, and motion planning of an industrial arm robot. In kinematics, operations of rotation and translation, and the notion of homogeneous transformations are introduced. Forward kinematic equations of rigid manipulators and inverse kinematics are derived. Velocity relationships are determined with the use of the Jacobian matrix. Path planning and trajectory of motion are also discussed in this course. The course incorporates a semester long hands-on project. Pre-requisites: MEEG 384 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 127 MEEG 490 MECHANICAL ENGINEERING DESIGN PROJECT I This course allows students to utilize and integrate the knowledge gained from the various courses taken previously and concurrently within the context of a final year capstone design project. Building upon previously learnt design process topics, advanced tools are introduced to help students develop conceptual alternatives, justify and select an optimum solution, develop an embodiment design, and build a full proposal for the prototype that they will construct and commission in the follow-on design course. Topics covered include PDS, QFD, Pugh analysis, DfX, FMEA, feasibility and economics analysis, and contemporary issues including professional and ethical responsibilities, engineering solutions in a global, environmental and societal context. Pre-requisites: STPS 251, Senior year standing or permission of Program Chair Co-requisites: None Restrictions: None Lecture/Lab/Credit:3:0:3 MEEG 491 MECHANICAL ENGINEERING DESIGN PROJECT II In this follow-on final year capstone design course students refine their embodiment design into a detailed design, and construct and commission the design prototype. In addition, students communicate their progress and final achievements through oral presentations and written reports. Pre-requisites: MEEG 490 Co-requisites: None Lecture/Lab/Credit:3:2:3 MEEG 293/393/493 SPECIAL TOPICS IN MECHANICAL ENGINEERING The course offers content not included in existing courses. A student can take multiple Special Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the Program Co-requisites: To be determined by the Program Restrictions: MEEG 293 is open to Sophomore students and above, MEEG 393 is open to Junior students and above, MEEG 493 is open to Senior students only. Lecture/Lab/Credit: 1-4 credits MEEG 394/494 RESEARCH TOPICS IN MECHANICAL ENGINEERING The course focuses on research-driven topics. A student can take multiple Research Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the Program Co-requisites: To be determined by the Program Restrictions: MEEG 394 is open to Junior students and above, MEEG 494 is open to Senior students only. Lecture/Lab/Credit: 1-4 credits MEEG 396/496 INDEPENDENT STUDY IN MECHANICAL ENGINEERING The course may offer content not included in existing courses in an independent study format based on a formal arrangement between the student and instructor. A student can take one or more Independent Study course (up to 6 credits). Independent Study courses require prior approval of the Program Chair and Provost (or designee). Pre-requisites: To be determined by the Program Co-requisites: To be determined by the Program Restrictions: CGPA:3.0, MEEG 396 is open to Junior students and above, MEEG 496 is open to Senior students only. Lecture/Lab/Credit: 1-6 credits 128 Materials Science and Engineering (MSEG) MSEG 334 MATERIALS SCIENCE This course is designed to introduce a study of the properties of engineering materials, the effect of material microstructure on those properties and the development and manipulation of microstructure through processing. Such an understanding is required for the analysis and selection of materials and processes for the design and manufacture of products, systems and structures. Prerequisites: CHEM 101, Chemistry I Corequisites: None Restrictions: MSEG 380 INTRO. POLYMER SCIENCE & ENGINEERING Definitions, industry overview, nomenclature, basic organic chemistry of polymers, polymerization, molecular weight and molecular weight distribution. Basic polymer structure and thermomechanical behaviour and structure property relationship. Mechanical properties, definitions, viscoelasticity, other mechanical properties. Basic rheology and introduction to polymer processing techniques, recycling. Prerequisites: CHEM 101, Chemistry I; PHYS191, Physics I Corequisites: None Restrictions: MSEG 2XX METALLURGICAL PROCESS CALCULATIONS Basic principles of mass & energy flow in metallurgical processes, principles of mass & energy conservation, basis thermodynamic principles applicable to metallurgical processes are introduced. The principles taught will be applicable to a selected variety of metallurgical processes from pyrometallurgical, hydrometallurgical & electrometallurgical extractive schemes to follow mass & energy flow. Calculations will be performed to determine material recovery and energy efficiencies in metallurgical processes. Thermochemical computer models and software will be introduced and examples of process calculations will be performed to compare theoretical models with plant performances. Prerequisites: MATH212, Calculus III; CHEM 102, Chemistry II; PHYS191, Physics I Corequisites: None Restrictions: MSEG 3XX PHYSICAL METALLURGY This course reviews crystallographic properties of metals and their interactions with metal defects and imperfections. The course also covers various structural and microstructural features of metals and their alloys, as well as principal physical properties such as electrical conductivity, thermal conductivity, heat capacity, thermal expansion, magnetic properties and optical properties. Prerequisites:MSEG334, Materials Science; PHYS241, Physics II Corequisites: None Restrictions: None 129 MSEG 3XX RHEOLOGY This course provides an introduction to various aspects of theoretical rheology, including: Newtonian fluids mechanics, linear and non-linear viscoelasticity, rheological flows, and constitutive equations. Also included the rheological measurement and industrial applications of rheometry in a number of different products. Prerequisites: MSEG380, Introduction to Polymer Science and Engineering; MATH261, Differential Equations Corequisites: None Restrictions: None MSEG 3XX POLYMER CHEMISTRY & REACTION ENGINEERING This course provides an introduction to the chemistry of polymerization and the polymer manufacturing process. It begins with basic concepts about polymers and polymerization and covers each major type of polymerization withrelevant kinetics. The qualitative effect of reactor design on polymer manufacture is discussed as well as actual polymer manufacturing processes including those taking place in the UAE. Course also includes Laboratory exercises to reinforce concepts in Polymer Chemistry and Reaction Engineering. Prerequisites: CHEM201, Organic Chemistry Corequisites: None Restrictions: None MSEG 3XX THERMODYNAMICS OF MATERIALS The course covers the fundamentals of thermodynamics and their application to a variety of materials and materials heat-processing problems. This includes the first law of thermodynamics and its application to equilibrium states and phase transformations as well as the second law of thermodynamics and the statistical interpretation of entropy and reversible processes. Also discussed in this course, the thermodynamic potential of systems under various conditions, Gibbs free energy as a function of temperature and pressure, state functions and properties, and extensive and intensive properties of thermodynamic systems. Prerequisites:PHYS191,Physics I Corequisites: None Restrictions: None MSEG 3XX BASIC MECHANICS This course is composed of two parts. The first part concentrates on the fundamentals of statics and the second part of this course covers the concepts of different types of stresses. Use of equilibrium equations to determine the internal loads in a certain structure as well as determining the centroid, first-and-second moment of inertia of an area are covered initially. The second part of this course covers relationships between the external loads and the intensity of internal forces acting within a body through the calculation of stresses in loaded members. Prerequisites:PHYS191, Physics I Corequisites: None Restrictions: None 130 MSEG 3XX TRANSPORT PHENOMENA Basic principles of heat flow, fluid flow, mass transport and reaction kinetics are introduced. The principles taught will be applicable to a wide variety of materials issues including processing, stability and environmental durability, and performance. Other aspects of transport phenomena are discussed including heat transfer, mass transfer, fluid flow and coupled transport phenomena. Prerequisites:MATH261, Differential Equations; PHYS191, Physics I Corequisites: None Restrictions: MSEG 3XX MICROSTRUCTURE OF MATERIALS An introduction to the relationships between microstructure and properties of materials, with emphasis on metallic and ceramic systems; Fundamentals of imperfections in crystalline materials on material behavior; Recrystallization and grain growth; Strengthening mechanisms: Grain refinement, Solid solution strengthening, Precipitation strengthening, and Microstructural strengthening; and Phase transformations. Prerequisites: MATH212, Calculus III; CHEM 102, Chemistry II; PHYS191, Physics I; MSEG 334, Materials Science Corequisites: None Restrictions: MSEG 3XX PHASE EQUILIBRIUM & TRANSFORMATIONS This course explores the mechanisms, thermodynamics and kinetics of transformations in metallic materials from both theoretical and experimental perspectives. The course includes the following topics: diffusional and diffusionless mechanisms, transformation, nucleation and growth, phase equilibrium and metastable phase diagrams, the influence of interfaces on equilibrium, ternary phase diagrams, isomorphous systems, three-phase equilibrium, four- phase equilibrium, and congruent transformation. The course also covers precipitation from solidification and its associated crystallography as well as precipitation mechanisms, such as age hardening and coarsening. Martensitic transformation and Bainitic transformation are also discussed. Prerequisites:MSEG3XX, Thermodynamics of Materials Corequisites: None Restrictions:None MSEG 3XX CORROSION & OXIDATION OF METALS This course covers both fundamental and practical aspects of materials corrosion with emphasis on metallic materials, and ways of preventing or retarding the corrosion process. The electrochemical theory of corrosion is introduced to describe material mass and thickness losses under various corrosive environments, as well as the thermodynamics and kinetics of corrosion processes. Corrosion case studies under various industrial environments such as aircraft, construction and petroleum industries are discussed including plain-carbon steels, stainless steels and common nonferrous alloys. Prerequisites: CHEM102, Chemistry II Corequisites: None Restrictions: 131 MSEG 3XX MATERIALS CHARACTERIZATION Materials are characterized on the basis of their microstructure (phase distribution), chemical composition (elemental distribution), properties (strength, toughness, hardness, etc.) and application (structural and non-structural). Materials are required to perform in multi-functional applications, and, thus have to be characterized for each. This course will build upon the knowledge gained in 3XXX: Microstructure of Materials and describe the tools, methods, measurement techniques, accuracy and applicable standards to elucidate the processing-structure-propertiesperformance relationships. Wet and dry chemical analysis techniques and mechanical property measurement methods will be described and demonstrated. Laboratory experiments to supplement the lectures. Prerequisites: MATH212, CHEM 102, PHYS191, MSEG 2XX: Materials Science, MSEG 3XX: Microstructure of Materials, MSEG 3XX: Physical Metallurgy. Corequisites: None Restrictions: MSEG 3XX MATERIAL KINETICS During the first half of the course, two fundamental kinetic processes; reaction kinetics and diffusion kinetics will be introduced and described in detail. The second half of the course shows students how to apply them to qualitatively and quantitatively model common kinetic processes relevant to materials science and engineering. Specific kinetic examples will include silicon and integrated circuit processing, gas transport through membranes, thin-film deposition, sintering, oxidation, carbon-14 dating, nucleation and growth, steel degassing, and fuel cell operation. Prerequisites: MSEG 3XX: Thermodynamics of Metals; MSEG 334: Materials Science Corequisites: None Restrictions: MSEG 3XX NON-FERROUS METALLURGY This course covers the physical metallurgy of non-ferrous alloys. The concepts of alloy design and microstructural engineering are also discussed, linking processing and thermodynamics to the structure and properties of non-ferrous metals. This course gives students knowledge of most typical non-ferrous alloy systems. This knowledge includes literacy in major alloy systems, with emphasis on microstructural evolution and structure-properties relations. Some description of relevant alloy applications will be included. Prerequisites: MSEG334, Materials Science Corequisites: None Restrictions:None MSEG 4XX EXTRACTIVE METALLURGY This course deals with extractive metallurgy, mining, iron ore dressing, physical separation techniques, flotation, dewatering. Emphasis is given to the extraction processes such as hydrometallurgy and electrometallurgy including leaching, solution purification, solvent extraction, metal winning, refining as well as pyrometallurgy including roasting, smelting, converting, and refining. Fuels, furnaces, metallurgical reactors, refractories, energy efficiency are covered along with the calculations based on flow sheets, heat and mass balances. Prerequisites:MSEG334, Materials Science Corequisites: None Restrictions: 132 MSEG 4XX METAL FORMING & PROCESSES The course focuses on the fundamentals of metal forming processes, mechanics of metal forming, formability of materials, tool and die design, design for manufacture, and economic aspects of the process. Emphasis is placed on analysis of bulk and sheet metal forming processes as applied to practical cases. Prerequisites:MSEG3XX, Basic Mechanics Corequisites: None Restrictions: MSEG 4XX INTRODUCTION TO SURFACE ENGINEERING This course introduces concepts and applications of surface engineering in the context of understanding various types of surface failures of engineering components and being able to select optimum materials and surface treatment solutions. The course is designed to study interactions between materials properties and the environment to which they are exposed. The mechanisms of surface modifications through processing are presented and compared in terms of surface properties improvement such as hardness, strength, adhesion, friction and corrosion resistance. Prerequisites: MSEG 3XX, Physical Metallurgy; MSEG 3XX, Microstructure of Metals Corequisites: None Restrictions: MSEG 490 SENIOR DESIGN I This course is the first part of a senior design project, runs during the first semester of the senior year. The course aims at teaching students how to utilize and integrate the knowledge earned from the various courses taken previously and concurrently within the context of a final year design project. Students will learn how to collect information related to their project, organize, and plan an open-ended project using resources from workshops, industry, library, internet and discussions with their supervisors and colleagues. The course will also give students the chance to practice and improve their oral and written communication skills by making oral presentations and submitting written interim reports throughout the semester. Prerequisites: Senior standing Corequisites: None Restrictions: MSEG 4XX STEEL MAKING TECHNOLOGIES This course discusses the fundamentals of metallurgical thermo-chemical reactions and their kinetics in view of understanding the metallurgical process in the iron and steel making industry, with an emphasis on ladle metallurgy. This includes the direct reduction of iron ore and particle reduction kinetics, as well as analysis of shaft furnace & blast furnace operations. Industrial processes are analyzed in terms of reactor design, smelting-reduction and the production of ferrous alloys. Continuous casting, sheet steel manufacture and methods of scale reduction during the forming process are also covered. Prerequisites:MSEG3XX, Extractive Metallurgy Corequisites: None Restrictions: 133 MSEG 4XX MATERIALS SELECTION IN MECHANICAL DESIGN This course develops a systematic procedure for selecting materials and processes leading to the subset which best match the requirements of a design. The approach emphasizes on design with materials rather than materials “science”, to help with the structuring of criteria for selection. The course integrates materials selection with other aspects of design. The relationships with the stages of design optimization and with the mechanics of materials are developed throughout. Prerequisites:MSEG4XX, Metal Forming & Processes Corequisites: None Restrictions: MSEG 4XX METALLURGICAL APPLICATION This course covers the metallurgy of industrial processes and failures with emphasis on applications in the oil and gas industry. This includes the metallurgical aspects of welding including microstructure and properties, thermal and chemical aspects of fusion welding and analysis of metallurgical failures. The course also covers typical failures such as corrosion, wear and creep. Prerequisites:MSEG3XX, Corrosion and Oxidation of Metals Corequisites: None Restrictions: MSEG 491 SENIOR DESIGN II This course runs during the second semester of the senior year. At this stage, students will be able to implement their plans and design processes outlined in Senior Design I. In this course, students will learn how to investigate materials behavior, properties and processing, by conducting experiments and simulation work to improve materials performance, processability and applications. Students will be able to improve their oral and written communication skills through oral presentations, posters, and project report submissions. Prerequisites: MSEG 490, Senior Design I Corequisites: None Restrictions: Petroleum Engineering (PEEG) PEEG 214 RESERVOIR ROCK PROPERTIES This course provides theoretical introduction to basic rock properties and their core-based measurements in the laboratory. Reservoir rock properties determined by conventional core analysis and special core analysis will be covered. It will be discussed how to obtain reliable core analysis data and the specific topics addressed include porosity and permeability, Darcy’s law and its applications/limitations, fluid saturations, wettability, capillary pressure, relative permeability, resistivity, compressibility and the effect of internal and external forces on rock physical properties. Pre-requisites: ENGR 101 Co-requisites: PEEG 215 Restrictions: None Lecture/Lab/Credit: 2:0:2 134 PEEG 215 RESERVOIR ROCK PROPERTIES LABORATORY This course is a laboratory component of the PEEG 214 reservoir rock properties course. It consists of practical laboratory sessions during which students conduct core analysis experiments measurements on the reservoir rock samples under both ambient and reservoir conditions, using state of the art equipment. The reservoir rock properties measured include porosity, air permeability, liquid permeability, saturation porosity, porous plate capillary pressure, rock and brine resistivity, brine density using a pycnometer, sieve analysis for grain size distribution and relative permeability. Students are also familiarized with the basic tools and equipment used and their safe operating procedures during the practical sessions. Students also compile the experimental data, present them graphically and analyze the data. Students work in groups of 4, but each student is expected to submit an independent technical lab report for each experiment performed. Pre-requisites: ENGR 101 Co-requisites: PEEG 214 Restrictions: None Lecture/Lab/Credit: 0:3:1 PEEG 216 RESERVOIR FLUID PROPERTIES This course covers the basic characterization of reservoir fluids, their properties, and their measurement. Topics covered include phase behavior, density, saturation pressures, gas-oil ratios, shrinkage, viscosity and the compositional analysis of oil, gas, and brine. The importance and challenges of obtaining representative fluid samples are discussed in detail. Utilization of the data for reservoir management and reservoir modeling will also be introduced. Pre-requisites: MEEG 222, ENGR 101 Co-requisites: PEEG 217 Restrictions: None Lecture/Lab/Credit: 2:0:2 PEEG 217 RESERVOIR FLUID PROPERTIES LABORATORY The laboratory sessions of this course cover a range of experimental work on fluid samples, known as pressure-volume-temperature study, which give students a basic understanding of how laboratory data are obtained and the factors that influence their reliability. Most of the experiments are performed using real oil and gas samples. Twelve experiments are designed to help students understand the principals and laws governing reservoir fluid behavior that are discussed in theory (PEEG 216). Pre-requisites: None Co-requisites: PEEG 216 Restrictions: None Lecture/Lab/Credit: 0:3:1 135 PEEG 252 MECHANICS OF MATERIALS FOR PETROLEUM ENGINEERING This course provides introduction to Statics and selection of the most important topics in Strength of Materials with emphasis on geomaterials. Forces and force couples, force system resultants, free body diagrams, equations of equilibrium, and internal/external forces are introduced first and then applied to problems of stress analysis in various structural members and rocks, considering successively axial loading, torsion and pure bending. The concept of stress tensor is introduced, relations between stress and strain in brittle and ductile materials explained and the significance of elastic parameters highlighted. Stress transformation equations are also covered and students are introduced to laboratory methods of measuring rock strength. Practical examples of stress analysis are given in the context of structural members, wellbores and boreholes, and the concept of failure criterion is introduced using Mohr-Coulomb failure criterion as an example. This course is required for all Petroleum Engineering majors. Pre-requisites: MATH 161, PHYS 191 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 PEEG 314 WELL LOGGING This course introduces the various well logging methods, tools and their principles of operation with emphasis on the relationship between measurements and reservoir petrophysical properties. Conditions and limitations for applications of various logs are discussed. Graphical and analytical methods used to determine formation composition, contents, and its potential for production are developed and applied. Computer and commercial software packages are used to handle data, create graphs and log traces, and determine reservoir parameters. Pre-requisites: PHYS 241, PEEG 214 Co-requisites: PEEG 321 Restrictions: None Lecture/Lab/Credit: 3:0:3 PEEG 315 RESERVOIR CHARACTERIZATION Reservoir Characterization course is, in fact, part I of reservoir simulation technology path in the PetroleumEngineering Program at PI. The students will be learning about reservoir static modeling through this course (PEEG 315) in the junior level and then they will be introduced to reservoir dynamic modeling leveraging from the course Reservoir Simulation (PEEG 435) in the senior level. The need to have a clear vision of the reservoir and be able to mimic this vision in physical, mathematical or numerical sense, enables reservoir engineers to understand the principal qualities of the reservoir and analyze its behavior under various production and EOR scenarios. This course will introduce the student to reservoir characterization, the need for synergy between disciplines, and to different modeling approaches, techniques and methods, currently used in the oil industry for building a geological or static model. In the lab part of this course, the student will have the opportunity to use software modeling tools (options are: Irap RMS, Petrel, GSLIB etc), to build the reservoir in 3D, with devoted recognition to structure, facies distributions, petrophysical properties and fluid distributions. Heterogeneity of the reservoir and fault pattern layout is a major modeling issue to be discussed. With professional tutoring and supervision, the student will be able to perform a series of exercises that lead them to walk through the workflow process and, eventually, at the end of the course, the student will be able to generate an upscaled model ready to be used in the subsequent flow simulation course (senior level). Pre-requisites: PEEG 216, PEEG 314, PGEG311 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:2:3 136 PEEG 321 DRILLING ENGINEERING I This is an introductory level drilling course which introduces rotary drilling process and basic drilling rig components to the students who have no prior knowledge on oil well drilling technology. Hands on practical sessions with the help of drilling simulators will be used to practice basic drilling operations as well as popular well control procedures. At the end of the course the students should be able to assess formation pressures and fracture strengths; design mud programs and casing shoe depths; design basic components of a drilling rig to meet a given objective; select the most suitable operational parameters for some key drilling equipment; and finally, be familiar with popular drilling problems such as well control, stuck pipe, etc. Pre-requisites: PEEG 252 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 PEEG 324 DRILLING ENGINEERING II This is an advanced level drilling course designed for students who have prior knowledge of drilling fundamentals. The course covers a range of topics from drill bits and tubular design, to drilling fluids and cementing. Upon completing this course, the students should be able to know IADC classification of drill bits, identify drill bits to meet given tasks, select bit operating parameters, select casing grades for a given well data, formulate and analyze drilling fluids and finally design cement job to meet a given objective. The class meets two hours per week. Pre-requisites: PEEG 321 Co-requisites: PEEG 325, MEEG 302 Restrictions: None Lecture/Lab/Credit: 2:0:2 PEEG 325 DRILLING ENGINEERING II LABORATORY This course consists of practical laboratory sessions in which students prepare drilling fluid samples and conduct a wide range of experimental measurements of the properties of the samples, under both ambient and reservoir conditions. The properties measured include Density, Rheology, Fluid Loss, Solid Content, Lubricity Characteristics, Drilling Fluid Contamination test, and Chemical Analysis Test, among others. The objective of this course is to familiarize the students with the basic tools and techniques to conduct experiments to measure properties of drilling fluids, using the appropriate safe operating procedures. Students also compile experimental data, present them graphically and also analyze them to explain some drilling related problems. A technical report is submitted for each experiment performed. Pre-requisites: PEEG 321 Co-requisites: PEEG 324 Restrictions: None Lecture/Lab/Credit: 0:3:1 137 PEEG 331 RESERVOIR ENGINEERING I This course presents the students with the derivation and application of zero dimensions reservoir models for reservoir management and performance prediction. Rock and fluid data requirements of these models are reviewed. Volumetric calculation methods for determination of oil and/or gas initial in-place are given. The subject of oil or gas initial and remaining reserve will be introduced, in relation with initial hydrocarbon in place through the concept of unit recovery, recovery efficiency and recovery factor. The course will also present the different types of hydrocarbon reservoirs, with its possible oil and gas drive mechanisms. The material balance equations are given and tailored for both volumetric and water drive gas reservoirs and for depletion, gas-cap drive, water drive and/or gravity segregation drives oil reservoirs. The reservoir performance of gas condensate reservoirs is also explained. The course will be supported by hands-on problems, and practical field examples. Pre-requisites: PEEG 214 or PGEG 381, PEEG 216, MEEG 302 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 PEEG 334 RESERVOIR ENGINEERING II In this course, key reservoir parameters required to calculate recovery factor, mobilization, displacement & sweep efficiencies, fractional flow analysis, and heterogeneity & gravity segregation interaction and their influence on displacement/recovery are fully covered. General principles relating to volumetric sweep that should be considered in planning EOR processes are reviewed. Principles of mobility control applicable to the development of oil/gas fields are also introduced. Unsteady-state water influx as related to production strategy is thoroughly discussed. Fundamentals of numerical dynamic reservoir simulation are also a major part of the course. Pre-requisites: PEEG 331, MATH 261 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 4:0:4 PEEG 341 COMPLETION AND WORKOVER The course presents a review of well completion and workover techniques. The objectives and optimum solutions of well completions for different field conditions are discussed including technical and economic considerations. The design of the tubing string, the most important downhole equipment of any hydrocarbon well, is discussed in detail. The ways of opening the formation for production are detailed and the different types of perforating oil and gas wells are analyzed. Workover procedures including remedial cementing, well stimulation methods are studied along with the required design procedures. Pre-requisites: PEEG 321 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 138 PEEG 342 PRODUCTION FACILITIES This course covers the description, applications, design, analysis and operational problems of surface production facilities. Topics include two-phase & three-phase separation, emulsion treatment, desalting, oil stabilization, water treatment, gas dehydration and sweetening, and storage and transportation. Pre-requisites: None Co-requisites: MEEG302/CHEG 302 or CHEG 351 or MEEG 354 Restrictions: None Lecture/Lab/Credit: 3:0:3 PEEG 397 PETROLEUM ENGINEERING INTERNSHIP Students are assigned to a variety of ADNOC’s operating companies where they will work on short- duration projects allowing them to apply the acquired knowledge from the PI, gain practical experience and become acquainted with the industry’s working environment. Each student is required to submit a written report and deliver a presentation on his work assignment. Pre-requisites: Senior year standing in PEEG with at least of 90 credit hours and CGPA > 2.0 Co-requisites: None Restrictions: Students enrolled in PEEG 397 cannot register for additional courses Lecture/Lab/Credit: 0:0:3 PEEG 420 WELL TREATMENT This course discusses the causes of production impairment and methods of improving well productivity using established well treatment methodologies. Two important area of a production system will be covered, the near wellbore formation (formation damage issues) and the production system (wellbore to separator, flow assurance issues). Topics include loss of productivity due to formation damage, asphaltene, wax and inorganic solid deposition along with detail mitigation methods. The course will also cover chemical based treatment methods to control/shut-off excessive water and gas production and injection water profile control. A significant part of the course will focus on diagnosis of problem, selection and application of chemicals, tools and hardware and designing specific well treatment operations. Pre-requisites: PEEG 341, Senior year Standing in PE Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 PEEG 423 HORIZONTAL AND MULTILATERAL WELL TECHNOLOGY This is a comprehensive course designed to familiarize petroleum-engineering students with the benefits and design of horizontal and multilateral wells. The topics covered include key details of drilling and completion of horizontal and multilateral wells, such as planning, drilling, surveying, tubular selection, failure analysis, cutting transport, hole-stability, cementing, centralizer spacing, etc. Students work on design examples and utilize a number of popular industry software packages. Pre-requisites: PEEG 324 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 139 PEEG424 UNDERBALANCED DRILLING TECHNOLOGY This course is designed to familiarize students with the five popular UBD techniques. These are Air/Natural Gas Drilling, Mist Drilling, Foam Drilling, Gasified Liquid Drilling and Flow Drilling. Benefits and limitations of each technique along with the design principles and operational procedures are discussed. Common problems pertinent to each technique and recommended procedures are also discussed. Pre-requisites: PEEG 324 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 PEEG 425 PRESSURE CONTROL This course is designed to introduce fundamental well control principles, procedures as well as well control equipment to the students who have completed their basic drilling engineering courses. In this course, students will learn concepts of formation pressure, static and dynamic well bore pressures; primary and secondary well control. They will be introduced well control principles procedures. The topics will cover, shut in procedures; kick circulation procedures; well control equipment will and finally, how to recognize and alleviate kick circulation problems. The course is designed to give students hands on training with the help of PI Drilling Simulators. Pre-requisites: PEEG 324 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 PEEG 436 WELL TESTING This course will address theoretical development of flow equations governing well testing in oil and gas wells. A formulation of flow equations in dimensionless form will be introduced. Line Source Analytical solutions of flow equations will be covered concentrating on semilog analysis. The principle of superposition will also be discussed. Deviation from the idealized model will be addressed and type curve solutions of the flow equations will be reviewed. The course will also cover oil and gas well testing techniques. Practical aspects of pressure analysis will be highlighted. A term project of the course will involve interpreting real well testing data using commercial well testing software. Pre-requisites: PEEG 314, PEEG 331, MATH 261 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 PEEG 437 NATURAL GAS ENGINEERING This course covers gas reservoirs rock and fluid Properties, including Darcy and non-Darcy flow phenomena near gas wells. Gas reserves estimation using linearized MBE and Decline Curve Analysis will be evaluated. Decline curves analysis of Fetkovich, Palacio and Blasingame and Agarwal and Gardner will be studied. Gas flow and gas well testing to evaluate reservoir characteristics will be covered, considering the pressure solution; p2 solution, Real Gas Pseudo Pressure solutions of the gas transient flow equation. Deliverability of gas wells will be determined using Multi-Rate draw down testing, flow after flow testing, Isochronal Testing, and Modified Isochronal Testing. Finally, Prediction of Future Performance and Ultimate Recovery form gas reservoirs will be studied. Pre-requisites: PEEG 331 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 140 PEEG 443 PRODUCTION SYSTEMS DESIGN AND ANALYSIS This course utilizes Nodal Analysis techniques for the design and performance analysis of the production system starting from the formation up to the production separator. Topics include inflow performance relationships, multiphase flow in horizontal, vertical and inclined pipes, overall well performance evaluation considering various nodes within the production system, and applications to design and analysis situations. In addition to applications to flowing wells, the application of NODAL analysis methods is discussed to the most important two versions of artificial lift techniques: gas lifting and production by electrical submersible pumps. Pre-requisites: PEEG 331, PEEG 341 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 PEEG445 PRODUCTION ENHANCEMENT This course discusses the causes of production impairment and methods of improving well productivity. Topics include loss of productivity due to formation damage, solids deposition, excessive water and gas production, and bottlenecks in the production system; and production enhancement by matrix treatments, remedial cementing and production profile control. Debottlenecking of the production system through Nodal analysis of the production system is also covered. Pre-requisites: PEEG 341, PEEG 443 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 PEEG 456 PETROLEUM RELATED ROCK MECHANICS This course covers the basic rock mechanics principles and topics such as nature of rock, rock deformability and rock stress, engineering properties of rocks from laboratory testing, and the effect of factors such as pore pressure, temperature and time on rock behavior. Scale effects, rock strength, brittle and ductile failure and mathematical approaches to stress-strain analysis in rocks, including stress transformations and constitutive representation of rock behavior, will be discussed. Several typical petroleum engineering applications such as calculations of borehole stresses, borehole stability analysis and reservoir compaction, will be given. Pre-requisites: PEEG 252 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 PEEG 460 PETROLEUM ECONOMICS AND RISK ANALYSIS The objective of this course is designed to develop the expertise of petroleum engineering students in the area of petroleum economics and risk/uncertainty analyses and their relation to decision making process in the petroleum industry. It introduces students to the concept of business economics implemented in modern petroleum industry. This approach improves students’ skills to utilize all available information about the reservoir and other related economies in depicting a realistic projection of the reservoir worth and the changes of business success. Pre-requisites: H&SS 251 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 4:0:4 141 PEEG490 PETROLEUM ENGINEERING DESIGN PROJECT I Capstone design experience in Petroleum engineering. The course focuses on team-oriented design projects involving Petroleum Production, Well drilling, Oil recovery or related design. Students participate in a design process that incorporates realistic engineering constraints such as applicability in the oil field and economics, as well as issues dealing with safety and ethics. Pre-requisites: Senior standing in Petroleum Engineering, PEEG 321, PEEG 331 Co-requisites: PEEG 315 Restrictions: Open to Petroleum Engineering students only Lecture/Lab/Credit: 0:3:1 PEEG491 PETROLEUM ENGINEERING DESIGN PROJECT II Capstone design experience in petroleum engineering. The course focuses on team-oriented design projects involving Petroleum Production, Well drilling, Oil recovery or related design. Students participate in a design process that incorporates realistic engineering constraints such as applicability in the oil field and economics, as well as issues dealing with safety and ethics. Pre-requisites: PEEG 490 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 PEEG 293/393/493 SPECIAL TOPICS IN PETROLEUM ENGINEERING The course offers content not included in existing courses. A student can take multiple Special Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the Program Co-requisites: To be determined by the Program Restrictions: PEEG 293 is open to Sophomore students and above, PEEG 393 is open to Junior students and above, PEEG 493 is open to Senior students only Lecture/Lab/Credit: 1-4 credits PEEG 394/494 RESEARCH TOPICS IN PETROLEUM ENGINEERING The course focuses on research-driven topics. A student can take multiple Research Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the Program Co-requisites: To be determined by the Program Restrictions: PEEG 394 is open to Junior students and above, PEEG 494 is open to Senior students only Lecture/Lab/Credit: 1-4 credits PEEG 396/496 INDEPENDENT STUDY IN PETROLEUM ENGINEERING The course may offer content not included in existing courses in an independent study format based on a formal arrangement between the student and instructor. A student can take one or more Independent Study course (up to 6 credits). Independent Study courses require prior approval of the Program Chair and Provost (or designee). Pre-requisites: To be determined by the Program Co-requisites: To be determined by the Program Restrictions: CGPA: 3.0, PEEG 396 is open to Junior students and above, PEEG 496 is open to Senior students only Lecture/Lab/Credit: 1-6 credits 142 Petroleum Geosciences (PGEG) Concentration in Petroleum Geophysics PGEG 210 EARTH MATERIALS This course introduces the fundamentals of mineralogy, including systematic chemistry and crystallography and physical and optical properties of minerals, emphasizing the carbonate group and silicate minerals. Students learn to use the petrographic microscope and to describe and identify a variety of rock-forming minerals in hand samples and petrographic thin- sections. Pre-requisites: PGEG 221 and CHEM 102 Co-requisites: PGEG210L Restrictions: None Lecture/Lab/Credit: 2:3:3 PGEG 220 GEOLOGY OF THE MIDDLE EAST This course covers application of the principles of stratigraphy and age dating methods, first introduced in Introduction to Geology and Geophysics. The course introduces biologic evolution theory and covers the evolution of Earth’s atmosphere and biosphere. The emphasis of the course is on the tectonic, stratigraphic, and geographic evolution of the Middle East, and particularly on paleo-environments, facies, and tectonic setting of UAE reservoir intervals. The principles of basin analysis, including the formation of organic-rich rocks and maturation of hydrocarbons, are introduced. Pre-requisites: PGEG 221 Co-requisites: PGEG 220L Geology of the Middle East Laboratory for Petroleum Geosciences Undergraduate Students Restrictions: None Lecture/Lab/Credit: 3:3:3 PGEG 220L GEOLOGY OF THE MIDDLE EAST LABORATORY During this course students will apply biostratigraphy, chronostratigraphy, paleogeography and rock identification techniques to understand the geological evolution of the Middle East and to interpret the depositional environment of UAE reservoir formation. The course includes at least one all-day field trip. Pre-requisites: PGEG 221 Co-requisites: PGEG 220 Geology of the Middle East Restrictions: None Lecture/Lab/Credit: 0:3:1 PGEG 221 INTRODUCTION TO GEOLOGY AND GEOPHYSICS An introduction to geology and geophysics, emphasizing the process that form and shape Earth, petroleum geology, and geophysics, and the geology of the UAE and the Middle East. Course topics include: origin of minerals and rocks; seismology; Earth’s gravity; geomagnetism; geologic time; plate tectonics; structural geology; sedimentary transport and the depositional environments of reservoirs; geo-hazards; hydrology; economic geology. The course includes at least one all-day field trip. Pre-requisites: ENGR 101 Co-requisites: PGEG 221L Restrictions: None Lecture/Lab/Credit: 2:3:3 143 PGEG 230 GEOLOGICAL MAPS An ability to read, interpret and apply geological and topographic maps to the Earth System is fundamental to the Earth Sciences. The accurate collection, recording and interpretation of high-quality fieldwork data is essential to a geologist’s understanding of Earth processes and environments. Through the application of practical exercises, students will learn to apply static two-dimensional representations in order to construct and understand three-dimensional subsurface geometries. Students will learn to employ the primary data-gathering techniques used by geologists in the field and the reasons for these. Pre-requisites: PGEG 221 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 1:6:3 PGEG 300 MATLAB FOR EARTH SCIENTISTS The course will introduce algorithms to numerically solve mathematical problems relevant to earth sciences problems with a focus on numerical methods programming using Matlab. First the course will cover the basics of Matlab operating environment and language for computing and plotting. It will be followed by solving non-linear algebraic equations, systems of linear equations, linear curve fitting, polynomial curve fitting, finite differences, numerical integration and differentiation and finally basic applications to earth sciences problems. Pre-requisites: MATH 212 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 2:3:3 PGEG 311 SEDIMENTARY PETROLOGY Sedimentary Petrology is concerned with the origin of sediment and sedimentary rock. The course covers sedimentary processes, facies, and diagenesis. Emphasis is on petrographic analysis of microfacies and diagenesis and on carbonate reservoirs and source rocks. Students learn how to characterize reservoirs using limited subsurface information from petrographic thin sections and cores. The course includes a four-day field trip. Pre-requisites: PGEG 220 Co-requisites: PGEG 311L Restrictions: None Lecture/Lab/Credit: 3:3:4 PGEG 321 STRUCTURAL GEOLOGY Structural geology is the study of deformed rock. The course deals with the range of structures produced in rock by deformation; with the role of structures in trapping petroleum and their effect on production; and with application of structural methods in E & P. Course topics include stress and strain; rheological behavior of rock; effects of time, temperature, and pressure on deformation; kinematic and dynamic analysis of deformed rock; the origin and me cha n is m s of fractures, faults, and folds; structural interpretation from seismic reflection, well, and other E&P data; mapping of subsurface structures from industry data; regional structural geology of the UAE. The course includes one three-day field trip. Pre-requisites: PGEG 221, PGEG 230, PHYS 191 Co-requisites: PGEG 321L Restrictions: None Lecture/Lab/Credit: 3:3:4 144 PGEG 323 REMOTE SENSING FOR EARTH SCIENCES APPLICATIONS & GIS The course covers the basic principles and essential skills of remote sensing using image visualization, processing and GIS (Geographical Information System) for geological and/or environmental mapping. After completing the course, students should understand the physical principles of remote sensing and be familiar with the major remote sensing satellites and datasets. The students will learn the basic skills of image visualization, processing, interpretation and data manipulation for mapping. The course emphasizes the use of satellite images as essential information source for fieldwork. Pre-requisites: ENGR101, MATH 212, PHYS 241 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 1:3:2 PGEG 331 IGNEOUS AND METAMORPHIC PETROLOGY An overview of igneous and metamorphic rocks as a background for discussing their origin and distribution in relation to plate tectonics. Course topics include rocks and Earth structure, structures, textures, chemistry, and mineralogy of igneous rocks; phase rule and phase diagrams; origin and movement of magmas; metamorphism and metamorphic rock texture, structures and mineralogy, metamorphic facies and metamorphic phase diagrams. Pre-requisites: PGEG 210 Co-requisites: PGEG 331L Restrictions: None Lecture/Lab/Credit: 2:3:3 PGEG 341 PALEONTOLOGY Paleontology is the study of past life. The course covers the application of taxonomic procedures to the identification of fossils and the application of paleontology in paleo-environmental and bio-stratigraphic analysis. Students learn about the fundamental morphology, modes of life, evolutionary trends, and time ranges of major macrofossil and microfossil groups. Emphasis is on fossil types that are important in the analysis and interpretation of petroleum reservoirs of the Middle East. The course includes at least one all- day field trip. Pre-requisites: PGEG 220 Co-requisites: PGEG 341L Restrictions: None Lecture/Lab/Credit: 2:3:3 PGEG 351 PETROLEUM GEOPHYSICS The course provides an introduction to the principles and methods involved in modern geophysical petroleum exploration. The course concentrates on physical principles and interpretation of seismic surveying and its application to petroleum exploration. Gravity, magnetics, electrical, and electromagnetic principles and survey techniques are covered, but in less detail. Students will learn about the equipment used, typical fieldwork design, numerical data corrections, and data processing for each survey method. The course includes at least three all-day field trips. Pre-requisites: PGEG 221, PHYS 241 Co-requisites: PGEG 351L Restrictions: None Lecture/Lab/Credit: 3:3:4 145 PGEG 361 SEDIMENTOLOGY AND STRATIGRAPHY Stratigraphy instructs in the sedimentological and stratigraphic methods used to analyze and interpret sedimentary sequences. Students will learn to interpret physical processes and depositional environments from sedimentary structures and textures, and to apply sequence stratigraphic methods to interpret and model facies and sedimentary basin evolution. The course incorporates modern and ancient examples from the Middle East, particularly from the UAE. The course includes five days of fieldwork. Pre-requisites: PGEG 311 Co-requisites: PGEG 361L Restrictions: None Lecture/Lab/Credit: 2:3:3 PGEG 371 DATA ANALYSIS AND GEOSTATISTICS This course introduces the conceptual basics of statistical analysis of geoscience data, and instructs students in how to apply statistical methods including geostatistics to interpret geoscience data and solve petroleum geoscience problems. Course topics include graphical representations, univariate statistics, probability, normal distributions, statistical inference, analysis of variance, bivariate correlation and regression analysis, directional data, circular statistics, Markov analysis, event series and time series analysis, analysis of spatially distributed data, trend surface analysis, kriging, and multivariate methods. Pre-requisites: PGEG 221, MATH 212 Co-requisites: PGEG 371L Restrictions: None Lecture/Lab/Credit: 3:3:4 PGEG 381 ROCK MECHANICS AND RESERVOIRS This course builds on material introduced in PGEG 321 and provides theoretical and practical introduction to basic physical and mechanical rock properties and their core-based measurements. Selected reservoir rock properties such as porosity, permeability, saturations, capillary pressures and relative permeability are introduced first. Then topics such as nature of rock, rock deformability, brittle and ductile behavior, rock stresses, stress transformations, rock strength and failure and rock testing methods are discussed. Concepts introduced in the classroom are reinforced through laboratory sessions. Pre-requisites: PGEG 321 Co-requisites: PGEG 381L Restrictions: None Lecture/Lab/Credit: 2:3:3 PGEG 397 FIELD PETROLEUM GEOLOGY Field Petroleum Geology is concerned with the study of lithologies and structures in the field. The course addresses vertical and horizontal variability in depositional facies and physical characteristics in reservoirs in three dimensions, and shows how physical variability affects petroleum capacity, flow, and production. Attention is paid to post-depositional diagenetic processes and their effect on reservoir evolution. Students make geological and petrophysical measurement of time and facies-equivalents to UAE carbonate reservoirs. The course includes two periods of two weeks of fieldwork, each followed by one week of data integration and report writing at the Petroleum Institute. Pre-requisites: PGEG 361, PGEG 321, PGEG 230 Co-requisites: None Restrictions: Students enrolled in PGEG 397 cannot register for additional courses Lecture/Lab/Credit: 0:0:4 146 PGEG 398 GEOPHYSICS INTERNSHIP Students are assigned to a variety of ADNOC’s operating companies or geophysical service companies where they will work on short-duration projects allowing them to apply the acquired knowledge from the PI, gain practical experience and become acquainted with the industry’s working environment. Each student is required to submit a written report and deliver a presentation on his/her work assignment. Pre-requisites: PGEG 351; PGEG 361; PGEG 411; CGPA > 2.0 Co-requisites: None Restrictions: Students enrolled in PEEG 398 cannot register for additional courses Lecture/Lab/ Credit: 0:0:3 PGEG 400 SEISMIC DATA ACQUISITION AND PROCESSING This course provides an introduction to 2D and 3D seismic data acquisition and processing for land and marine surveys. It will introduce an overview of seismic data acquisition for both land and marine environments. However the course will concentrate on processing reflection seismic data to produce a geologically interpretable seismic volume. This will be achieved through a comprehensive seismic data processing stream that will take the seismic data from the field to the final migrated volume. An introduction to advanced and modern techniques of seismic data processing to further enhance the seismic image will be covered. Pre-requisite: MATH 261, PEEG 300, PGEG 411 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:3:4 PGEG 401 PETROPHYSICS AND LOGGING This course presents the physical principles of well logging. PGEG 401 introduces students to geophysical measurements made under borehole and lab conditions. The course also demonstrates methods to correlate geophysical measurements and rock properties and prepares students to perform basic well log and core data interpretation. The course covers concepts of rock properties and their application in the oil industry; lab measurements of rock properties (porosity, permeability, density, resistivity, fluid saturation); lithology logs, porosity logs, fluid saturation and permeability estimation from well logs; and full well log interpretation. The course refers to rock mechanics from core and well log data. Pre-requisite: PEEG 216, PEEG 217, PGEG 371, PGEG 361 Co-requisites: PGEG 401L Restrictions: None Lecture/Lab/Credit: 3:3:4 PGEG 410 RESERVOIR GEOPHYSICS The course provides an introduction to reservoir geophysics with emphasis on carbonate reservoirs. The course concentrates on the integration of seismic data, well data, and petrophysical data. Various aspects of the traditional approach of exploration geophysics as well as modern aspects of reservoir geophysics will be covered. Pre-requisite: PGEG 351, PGEG 400 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:3:4 147 PGEG 411 REFLECTION SEISMOLOGY The most important method for finding and investigating reservoirs on a large scale is reflection seismology. This course covers the fundamental wave theory that is the basis for the method, and the seismic data acquisition, processing, and display techniques in such a way that one can map the underground and describe its characteristics. The course has a significant theoretical component, and includes class exercises using seismic software and display systems on realworld seismic data. A major component of the course is to design, acquire data, and interpret a seismic reflection survey. The course requires fieldwork. Pre-requisite: PGEG 351, PGEG 371 Co-requisites: PGEG 411L Restrictions: None Lecture/Lab/Credit: 3:3:4 PGEG 412 SEISMIC REFLECTION INTERPRETATION The course covers principles and practices of seismic reflection interpretation. Course topics include: seismic interpretation theory and principles; picking wavelets; well to seismic ties; synthetic seismograms; fault identification; time-to-depth conversion; seismic stratigraphy; 3D seismic interpretation; seismic fracture analysis and interpretation; and seismic attributes. Students will learn how to interpret varieties of processed seismic data using seismic data interpretation software. Emphasis is on interpretation of carbonate strata. Pre-requisite: PGEG 411 Co-requisite: PGEG 412L, PGEG 461 Restrictions: None Lecture/Lab/Credit: 3:3:4 PGEG 413 MICROPALEONTOLOGY Micropaleontology is the study of microscopic fossil organisms. This course offers an overview of the most common microfossil groups. Identification techniques, stratigraphic distribution of the major microfossil groups and their relation with the sedimentary environments will be explained. The applications and uses of each microfossil group (biostratigraphy, paleogeography, paleoenvironmental and paleoclimatic reconstructions) will be explained. Emphasis will be given on shallow-marine unicellular microorganisms of the Mesozoic and Cenozoic. Pre-requisite: PGEG 341 Co-requisite: None Restrictions: None Lecture/Lab/Credit: 3:2:3 PGEG 451 ENVIRONMENTAL GEOLOGY This course deals with how people interact with Earth’s natural systems. Environment profoundly controls social and economic systems but, simultaneously, humans are major agents of geologic change. The course covers natural hazards, landscape and soil characteristics, groundwater, surface water, climate change, and ethics of environmental issues, emphasizing the environment and environmental issues of the UAE. The course includes a one-day field trip. Pre-requisites: PGEG 221, CHEM 102 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 148 PGEG 461 RESERVOIR CHARACTERIZATION PROJECT The course introduces and applies the principles and practices used to characterize petroleum reservoirs using core, structural, seismic, petrographic, and petrophysical data. Emphasis is on depositional geometries, petrophysical properties, and compartmentalization of carbonate reservoirs. Much of the coursework involves characterizing and designing a model of a UAE reservoir integrating multiple datasets. Pre-requisites: PGEG 361 Co-requisites: PGEG 412, PGEG 461L Restrictions: None Lecture/Lab/Credit: 2:6:4 PGEG 471 PETROLEUM SYSTEMS PROJECT This course involves completion of a project in the student’s area of interest in some area of petroleum geology or geophysics. Students must arrange for supervision from an instructor and the project must be approved by the Petroleum Geosciences Program. The course consists mostly of independent project work. Pre-requisites: PGEG 401, PGEG 411, STPS 251 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 1:6:3 PGEG 293/393/493 SPECIAL TOPICS IN PETROLEUM GEOSCIENCES The course offers content not included in existing courses. A student can take multiple Special Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the program Co-requisites: To be determined by the program Restrictions: PGEG 293 is open to Sophomore students and above, PGEG 393 is open to Junior students and above, PGEG 493 is open to Senior students only Lecture/Lab/Credit: 1-4 credit hours, variable dependent on credit hours. PGEG 394/494 RESEARCH TOPICS IN PETROLEUM GEOSCIENCES The course focuses on research-driven topics. A student can take multiple Research Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the program Co-requisites: To be determined by the program Restrictions: PGEG 394 is open to Junior students and above, PGEG 494 is open to Senior students only Lecture/Lab/Credit: 1-4 credit hours, variable dependent on credit hours. PGEG 396/496 INDEPENDENT STUDY IN PETROLEUM GEOSCIENCES The course may offer content not included in existing courses in an independent study format based on a formal arrangement between the student and instructor. A student can take one or more Independent Study course (up to 6 credits). Independent Study courses require prior approval of the Program Chair and Provost (or designee). Pre-requisites: To be determined by the program Co-requisites: To be determined by the program Restrictions: CGPA: 3.0, PGEG 396 is open to Junior students and above, PGEG 496 is open to Senior students only Lecture/Lab/Credit: 1-6 credit hours dependent on credit hours. 149 Physics (PHYS) PHYS 060 INTRODUCTION TO UNIVERSITY PHYSICS PHYS 060 is a developmental course that addresses essential skills needed for success in PHYS 191. The curriculum is designed to be student-centered with an emphasis on guided inquiry. The course focuses on the development of concepts involving everyday phenomena. Course activities help students develop representations, qualitative and quantitative problem solving skills. Students who are recommended to enroll in this course are identified through their performance on the PI placement test. Pre-requisites: MATH060 or Placement Test Co-requisites: None Restrictions: None Lecture/Studio Credit: 2:4:4 (Credits not counted toward graduation) PHYS 191 PHYSICS I – MECHANICS This is a first university course in physics that covers the basic principles of mechanics using vectors and calculus. The fundamental concepts are presented as well as applications of kinematics and kinetics of particles and solid bodies, including Newton’s Laws, energy and momentum principles, oscillations and waves. Pre-requisites: MATH 111 and (PHYS060 or Placement Test) Co-requisites: MATH 161 Restrictions: None Lecture/Studio Credit: 2:4:4 PHYS 241 PHYSICS II - ELECTROMAGNETISM AND OPTICS This is a continuation of PHYS 191 (Physics I – Mechanics). The course introduces students to the fundamental laws of electricity and magnetism, electromagnetic devices, the electromagnetic behavior of materials, applications to simple circuits, electromagnetic radiation, and an introduction to optical phenomena. Pre-requisites: MATH 161, PHYS 191 Co-requisites: MATH 212 Restrictions: None Lecture/Studio Credit: 2:4:4 PHYS 341 MODERN PHYSICS WITH APPLICATIONS This course aims to instill in the student an appreciation of the concepts and methods of twentiethcentury Physics, and to link this with insight into modern technological applications including lasers, light polarization techniques, radioactive dating, activation analysis, nuclear medicine, and semiconductor devices. The fundamental link between experiment and theory is stressed and discussed throughout and students will achieve a broader perspective about the empirical basis of modern Physics. Topics to be covered include the radiation and propagation of electromagnetic waves, the theory of special relativity, and the wave-particle duality of photons and ‘material’ particles. Pre-requisites: PHYS 241 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:Variable:3144 150 PHYS 393 SPECIAL TOPICS IN PHYSICS (INTRODUCTION TO NANOPHYSICS AND NANOTECHNOLOGY) This is an introduction to the key concepts and principles of the emerging field of Nanotechnology. The course is intended for a multidisciplinary audience. It will introduce topics such as size and scale dependent properties of Nanostructures, their synthesis, fabrication and characterization using Scanning Electron Microscopy (SEM), Transmission Electron Microscopy (TEM), and Atomic Force Microscopy (AFM). Special focus will be given to nanoscale-devices and their engineering applications. Pre-requisites: PHYS 241 Co-requisites: None Restrictions: None Lecture/Lab/Credit: 3:0:3 PHYS 293/393/493 SPECIAL TOPICS IN PHYSICS The course offers content not included in existing courses. A student can take multiple Special Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the Department Co-requisites: To be determined by the Department Restrictions: PHYS 293 is open to Sophomore students and above, PHYS 393 is open to Junior students and above, PHYS 493 is open to Senior students only Lecture/Lab/Credit: 1-4 credits PHYS 394/494 RESEARCH TOPICS IN PHYSICS The course focuses on research-driven topics. A student can take multiple Research Topics courses with different content for credit subject to program approval. Pre-requisites: To be determined by the Department Co-requisites: To be determined by the Department Restrictions: PHYS 394 is open to Junior students and above, PHYS 494 is open to Senior students only Lecture/Lab/Credit: 1-4 credits PHYS 396/496 INDEPENDENT STUDY IN PHYSICS The course may offer content not included in existing courses in an independent study format based on a formal arrangement between the student and instructor. A student can take one or more Independent Study course (up to 6 credits). Independent Study courses require prior approval of the Department Head and Provost (or designee). Pre-requisites: To be determined by the Department Co-requisites: To be determined by the Department Restrictions: CGPA: 3.0, PHYS 396 is open to Junior students and above, PHYS 496 is open to Senior students only Lecture/Lab/Credit: 1-6 credit 151 Directory of the Institute Governing Board H.E. Dr. Sultan Ahmed Al Jaber Chairman; C h i e f E x e c u t i v e O f f i c e r , A D N O C Mr. Abdul Munim Saif Al Kindy Deputy Chairman (ADCO) Mr. Ali Rashid Al Jarwan Member (ADMA) Mr. Abdul Karim Al Mazmi Member (BP) Mr. Andrew Vaughan Member (SHELL) Mr. Yosuke Ueda Member (JODCO) Mr. Hatem Nusseibeh Member (TOTAL) Dr. Nigel Middleton Member (CSM) Dr. Thomas Hochstettler President (PI) Institutional Advisory Board Dr. Thomas Hochstettler President (PI) Dr. Murray Ross Gray SVP Academic and Provost (PI) Mr. Nick Cochrane Dyet Special Advisor to the Chief Representative (BP) Dr. Khalid Aziz Stanford University Dr. Adel Sedra University of Waterloo Dr. Frederic Sarg Colorado School of Mines Dr. Frank Bates University of Minnesota Dr. Darryll J. Pines University of Maryland Mr. Ali Al Shamsi Director, Strategy and Coordination, ADNOC Mr. Abdulla Al Minhali Manager, Gas Processing Directorate, ADNOC Ms. Aseel Hammodi Vice President, Talent and Capability, ADCO Mr. Fareed Abdulla Senior Vice President, NEB - ADCO 152 Institutional Advisory Board Dr. Thomas Hochstettler President (PI) Dr. Murray Ross Gray SVP Academic and Provost (PI) Mr. Nick Cochrane Dyet Special Advisor to the Chief Representative (BP) Dr. Khalid Aziz Stanford University Dr. Adel Sedra University of Waterloo Dr. Frederic Sarg Colorado School of Mines Dr. Frank Bates University of Minnesota Dr. Darryll J. Pines University of Maryland Mr. Ali Al Shamsi Director, Strategy and Coordination, ADNOC Mr. Abdulla Al Minhali Manager, Gas Processing Directorate, ADNOC Ms. Aseel Hammodi Vice President, Talent and Capability, ADCO Mr. Fareed Abdulla Senior Vice President, NEB - ADCO 153 Full-Time Faculty A Abbas, Elrashid Yousif, Ph.D., Omdurman Islamic University, Sudan, 2007, M.A., Khartoum International Institute for Arabic Language, Sudan, 1990, B.A., Omdurman Islamic University, Sudan, 1983, Assistant Professor in Arts and Sciences. Abbedrabo, Soufiane, Ph.D., M.S., New Jersey Institute of Technology, 1998, 1997, B.A., Rutgers University/NJIT, 1993, Associate Professor in Physics. Abdeljabbar, Alrazi, Ph.D., University of South Florida, 2012, M.S., B.S., University of Jordan, 1996, 1992, Assistant Professor in Mathematics. Abdel-Magid, Youssef, Ph.D., M.S., University of Manitoba, 1976, 1972, B.S., Cairo University, 1969, Professor in Electrical Engineering and Acting Dean of the Graduate School. Abou Khousa, Mohammed, Ph.D., Missouri University of Science and Technology, 2009, M. Sc., Concordia University, 2005, B. Sc., American University of Sharjah, 2003, Assistant Professor in Electrical Engineering. Abu Haija, Mohammad, Ph.D., Technical University of Berlin, 2006, M.S., B.S., Yarmouk University, 1997, 1995, Assistant Professor in Chemistry. Afari, Ernest, Ph.D., Curtin University, 2012, M. Sc., University of British Columbia, 1989, Assistant Professor in Mathematics. Agyeman, Kofi, Ph.D., S.M., Massachusetts Institute of Technology, 1976, B.S., University of Ghana, 1970, Professor in Physics. Ahmad, Jamal, Ph.D., M.S., North Carolina State University, 1993, 1986, B.S., Birzeit University, 1986, Associate Professor in Mechanical Engineering. Ainane, Sami, Ph.D., University of Maryland, 2012, B.S., University of Grenoble, 1980, Associate Professor in Mechanical Engineering and Head of General Studies. Al Aasm, Ihsan, Ph.D., University of Ottawa, 1985, M.S., B.S., Baghdad University, 1997, 1974, Professor in Petroleum Geosciences. Al Alili, Ali, Ph.D., M.S., University of Maryland, 2012, B.S., Arizona State University, 2006, Assistant Professor in Mechanical Engineering. Al Allaf, Mashhad, Ph.D., University of Tennessee, 1995, M.A., B.A., University of Baghdad, 1985, 1981, Associate Professor in Islamic Studies. AlAmeri, Waleed S., Ph.D., M.Sc., Colorado School of Mines, 2015, 2010, B. Sc., Louisiana State University, 2006, Assistant Professor in Petroleum Engineering. 154 Al-Durra, Ahmed, Ph.D., M.S., B.S., The Ohio State University, 2010, 2007, 2005, Assistant Professor in Electrical Engineering. Alfantazi, Akram, Ph.D., M.A. Sc., Queen’s University, 1994, 1991, B. Eng., Laurentian University, 1988, Professor in Chemical Engineering. Al Hajri, Ebrahim, Ph.D., University of Maryland – College Park, 2009, M.S., University of Colorado – Denver, 2003, B.S., University of Arizona, 2001, Associate Professor in Mechanical Engineering and Director of External Relations and Collaboration. Al Hammadi, Khalid, Ph.D., North Carolina State University, 2006, M.S., Vanderbilt University, 1998, B.S., United Arab Emirates University, 1992, Assistant Professor in Electrical Engineering. Al Hanai, Mariam, M.S., Marquette University, 1984, B.S., Universidad Metropolitana, 1977, Lecturer in Mathematics. Alhassan, Saeed, Ph.D., Case Western Reserve University, 2011, M.S., Colorado School of Mines, 2006, B.E., Vanderbilt University, 2003, Assistant Professor in Chemical Engineering and GRC Director. Al Hosani, Khalifa, Ph.D., The Ohio State University, 2011, M.S., B.S., University of Notre Dame, 2007, 2005, Assistant Professor in Electrical Engineering and Director of Internship. Ali, Mohammed, Ph.D., Oxford University, 2003, M.S., University of Birmingham, 1998, B.S., University of Wales, 1997, Assistant Professor in Petroleum Geosciences. Alifu, Alip Mohamed, Ph.D., Free University of Berlin, 2002, Assistant Professor in Mathematics. Allison, David, Ph.D., Teesside Polytechnic, 1986, M.S., University of Kent, 1981, B.S., University of London, 1979, Assistant Professor in Mathematics. Allred, Jessica, M.S., City College of New York, 2011, B.A., Brigham Young University, 2006, Lecturer in English. Al Kobaisi, Mohammed, Ph.D., M.S., B.S., Colorado School of Mines, 2010, 2005, 2000, Assistant Professor in Petroleum Engineering. Al Mansoori, Ali, Ph.D., Imperial College London, 2006, B.S., Florida Institute of Technology, 2002, Associate Professor in Chemical Engineering and Dean of Engineering. Al Marzouqi, Hasan, Ph.D., Georgia Institute of Technology, 2014, M.Sc., B.Sc., Vanderbilt University, 2006, 2004, Assistant Professor in Electrical Engineering. Almaskari, Fahad, Ph.D., M.Sc., University of Manchester, 2010, 2004, B.Sc., University of Arizona, 2003, Assistant Professor in Mechanical Engineering. Al Sawalhi, Jamal, Ph.D., M.S., B. S., Purdue University, 2014, 2011, 2009, Assistant Professor in Electrical Engineering. 155 Al Sayari, Naji, Ph.D., University of Manchester, 2011, Assistant Professor in Electrical Engineering. Al Shami, Abdullah, Ph.D., University of Manchester, 1992, I.L.M., I.L.B., Islamic University of Muhammad Bin Saud, 1986, 1983, Professor in Islamic Studies. Alshehhi, Mohamed, Ph.D., University of Maryland – College Park, 2009, M.Sc., University of Colorado – Denver, 2003, B.S., University of Arizona, 2001, Assistant Professor in Mechanical Engineering and Director of Strategic Planning. Al Shoaibi, Ahmed, Ph.D., M.S., Colorado School of Mines, 2008, 2006, B.S., Florida State University, 2001, Associate Professor in Chemical Engineering and Dean of Academic Affairs. Alsumaiti, Ali M., Ph.D., M.S., Colorado School of Mines, 2011, 2006, B.S., Case Western Reserve University, 2003, Assistant Professor in Petroleum Engineering. Al Suwaidi, Aisha, Ph.D., University of Oxford, 2012, M.S., University of Kansas, 200, B.S., University of Arizona, 2004, Assistant Professor in Petroleum Geosciences. Al Wahedi, Khaled, Ph.D., Imperial College London, 2009, M.S., B.S., Case Western Reserve University, 2000, 1999, Assistant Professor in Electrical Engineering. Al Wahedi, Yasser, Ph.D., M.Sc., University of Minnesota, 2015, 2012, B.Sc., The Petroleum Institute, 2006, Assistant Professor in Chemical Engineering. Amer, Saed, Ph.D., Tennessee State University, 2012, Assistant Professor in Arts and Sciences. Ameur, Ahmed, Lecturer in Mathematics. Anderson, Alliya, M.A., University of San Francisco, 2007, B.S., Oklahoma State University, 2004, Lecturer in English. Andrew, Matthew, M.A., Macquarie University, 2010, B.A., Pennsylvania State University, 1998, Lecturer in English. Aoudi, Ziad, M.A., Murdoch University, 2012, B.S., Victoria University, 2000, Lecturer in Chemistry. Atanas, Jean-Pierre, Ph.D., DEA, Université Pierre et Marie Curie, 1999, 1996, B.Sc., Lebanese University, 1994, Assistant Professor in Physics. Aupa’au, Juliana, B.A., Auckland University, 1983, Lecturer in English. Ayish, Nader, Ph.D., George Mason University, 2003, M.A., University of Houston, 1996, B.A., The Ohio State University, 1989, Assistant Professor in Communication. Aynedjian, Hagop, M.S., Université Paul Sabatier – Toulouse III, 2005, “Maitrise”, B.Sc., Université Saint Joseph, 2003, Lecturer in Physics. 156 B Balfaqeeh, Muna, Ph.D., M.A., University of London (SOAS), 2007, 2003, B.A., United Arab Emirates University, 1999, Assistant Professor in Communication and Director of the Academic Bridge Program. Banat, Fawzi, Ph.D., M.Sc., B. Sc., McGill University, University of Jordan, 1995, 1991, 1988, Professor in Chemical Engineering and Chair of Chemical Engineering. Barkat, Braham, Ph.D., Queensland Institute of Technology, 2000, M.S., University of Colorado, 1988, State Engineer, Ecole National Polytechnique d’Alger, 1985, Professor in Electrical Engineering. Barrow, Mara, M.A., B.A., Monterey Institute of International Studies, 1997, 1996, Lecturer in English. Barsoum, Imad, Ph.D., Royal Institute of Technology, Sweden, 2008, M.Sc., University of Utah, 2002, Assistant Professor in Mechanical Engineering. Beig, Abdul Rahman, Ph.D., M.E., Indian Institute of Science, 2004, 1998, B.E., Karnataka Regional Engineering College, 1989, Associate Professor in Electrical Engineering and Deputy Chair of Electrical Engineering. Belhaj, Hedi, Ph.D., Dalhousie University, 2004, Technical University of Nova Scotia, 1990, University of Tripoli (previously El-Fateh University), 1982, Associate Professor in Petroleum Engineering. Berrouk, Abdallah Sofiane, Ph.D., The University of Manchester, 2007, M.S., University of Aberdeen, 2003, Men., National Institute of Mechanical Engineering, Boumerdes, 1995, Associate Professor in Chemical Engineering. Blouin, Denis, M.S., B. Sc., Laval University, 1989, 1985, Lecturer in Mathematics. Bouchalkha, Abdellatif, Ph.D., Oklahoma State University, 1993, M.S., Oklahoma State University, 1989, B.S., Central State University, 1986, Associate Professor in Physics and Head of Physics. Boiko, Igor, D.Sc., Ph.D., M. Sc., Tulsa State University, 2009, 1990, 1984, Professor in Electrical Engineering. Bouabid, Ali, Ph.D., M. Sc., University of Virginia, 2013, 2004, M. Sc., B. Sc., Conservatoire des Arts et Metiers, 1987, 1985, Assistant Professor in General Studies. Bouzidi, Youcef, Ph.D., University of Alberta, 2003, M.S., Columbia University, 1984, B.S., Algerian Petroleum Institute, 1980, Associate Professor in Petroleum Geosciences. Bradley, Curtis, Ph.D., M.A., Rice University, 1997, 1992, B.S., Oregon State University, 1985, Associate Professor in Physics. 157 Brandt, Caroline, Ph.D., University of East Anglia, 2004, M.A., University of Surey, 1996, M.A. (Hons), University of Edinburgh, 1980, Cambridge ESOL Diploma (DELTA), 1985, Cambridge ESOL Certificate (CELTA), 1982, Associate Professor in Communication and Head of Communication. Bruno, Pierre Paolo, Ph.D., University “Federico II”, 1997, M. Sc., Politecnico di Torino, 1992, B. Sc., “University “Federico II”, 1988, Assistant Professor in Petroleum Geosciences. Bouzidi, Yousef, Ph.D., University of Alberta, 2003, M.S., Columbia University, 1984, B.S., Algerian Petroleum Institute, 1980, Assistant Professor in Petroleum Geosciences. Burkett, Theodore, M.A., B.A., University of Connecticut, 1997, 1992, Lecturer in English. Bursiewicz, Virpi, M.A., B. A., University of Jyvaskyla, 1996, Lecturer in English. C Ceriani, Andrea, Ph.D., M.Sc., University of Pavia, Italy, 2001, 1995, Associate Professor in Petroleum Geoscience, Deputy Chair, Petroleum Geoscience. Cerimovic, Meliha, M.A., University of Technolgoy, Sydney, 2008, B.A., University of Sarajevo, 2006, Lecturer in English. Chandrasekar, Srinivasa, Ph.D., Indian Institute of Technology, 1993, M.S., Coimbatore Institute of Technology, 1987, Associate Professor in Chemical Engineering. Clark, John, M. Sc., Curtin University of Technology, 2002, B.A., B. Sc., Victoria University of Wellington, 1992, 1981, Dipl. Tchg., Christchurch Teachers’ Training College, 1982, Lecturer in Mathematics. Corbin, Shari, M.A., Diploma of Applied Linguistics, University of Victoria, BC, 2002, 1996, B.A. Geography, 1987, Carleton University, Lecturer in English. Craig, Robert, M.A., University of Essex, 1987, Diploma in Teaching English as a Foreign Language, Institute of Education, University of London, 1981, Senior Lecturer in Communication. Cubero, Samuel, Ph.D., University of Southern Queensland, 1998, Assistant Professor in Arts and Sciences. D Dallas, Andrea, Ph.D., University of Florida, 2008, M.A., University of Florida, 2004, M.Ed., Framingham State College, 2001, B.A., Florida International University, 1999, Assistant Professor in Communication. Dalton, David, M.A., University of Sheffield, 1994, B.S., Birmingham University, 1978, Senior Lecturer in Communication. 158 Dean, Kevin, Ph.D., King’s College, 1981, M.S., University of Liverpool, 1978, B.S., University of Hull, 1977, Associate Professor in Physics. Deveci, Tanju, Ph.D., Ankara University, 2011, M.A., Middle East Technical University, 2003, B.A., Ankara University, 1994, Assistant Professor in Communication. Dib, Khalid, Ph.D., North Dakota State University, 1999, M.S., Eastern New Mexico University, 1992, B.S., Iowa State University, 1990, Assistant Professor in Mathematics. Didenko, Andriy, Ph.D., M.S., Odessa National University, 1986, 1978, Assistant Professor in Mathematics and Head of Mathematics. Dimmitt, Nicholas, Ph.D., University of Southern California, 1994, M.A., B.A., San Francisco State University, 1985, 1983, Assistant Professor in Communication. E Ehrenberg, Stephen, Ph.D., University of California Los Angeles, 1978, M. Sc., University of California Davis, 1973, B.A., Occidental College, Professor in Petroleum Geosciences. Eide, Constance, M.Sc., Aston University, 2011, B.A., St. Olaf College, 1962, Lecturer in English. El Kadi, Mirella, Ph.D., University of Lausanne, 1993, Higher Studies, University of Lausanne, 1988, B.S., Lebanese University, 1986, Assistant Professor in Chemistry. El Sadaany, Ehab Fahmy, Ph.D., University of Waterloo, 1998, M. Sc., B. Sc., Ain Shams University, 1990, 1986, Professor in Electrical Engineering. Elsharkawy, Adel, Ph.D., Colorado School of Mines, 1990, M.S., B. S., Suez Canal University, 1985, 1978, Professor in Petroleum Engineering. El Sheakh, Ahmed, Ph.D., M.S., RWTH-Aachen University, 1990, 1983, B.S., Menoufia University, Senior Lecturer in Computing. El-Sinawi, Ameen, Associate Professor in Mechanical Engineering. El-Sokkary, Wael, M.A., University of Maryland, 2003, B.A., University of Ain Shams, 1992, Lecturer in English. Eveloy, Valerie, Ph.D., Dublin City University, 2003, M.S., National Institute of Applied Science, 1994, DEUG, University of Rennes, 1990, Associate Professor in Mechanical Engineering. 159 F Fahmi, Samira, M.S., University of Alberta, 2006, B.A., Ibn Tofail University, 2000, Lecturer in English. Fernandes, Ryan, Ph.D., University of Kentucky, 1991, M.S., B.S., University of Bombay, 1981, 1979, Associate Professor in Mathematics. Fiorini, Flavia, Ph.D., M.S., University of Modena, 2002, B.S., University of Bologna, 1992, Assistant Professor in Petroleum Geosciences. G Garinger, Dawn, M. Ed., B.A., University of Alberta, 1999, 1994, Lecturer in English. Ghosh, Bisweswar, Ph.D., Nagpur University, India, 1995, M.Sc., IIT, India, 1984, B. Sc. (Hons), Burdwan University, India, 1981, Associate Professor in Petroleum Engineering. Goharzadeh, Afshin, Ph.D., University of Le Havre, 2001, M.S., University of Rouen, 1998, B.S., University of Le Havre, 1997, Associate Professor in Mechanical Engineering. Gomes, Jorge Salgado, Ph.D., M.Sc., Heriot-Watt University, 2000, 1991, M. Eng., B. Sc., Oporto University (1982, 1980), PARTEX Chaired Professor in Petroleum Engineering. Gray, Murray Ross, Ph.D., California Institute of Technology, 1984, M. Eng., University of Calgary, 1980, BaSc (Hons), University of Toronto, 1978, Senior Vice President, Academic and Provost. Griffiths, Huw, Ph.D., Cardiff University, B. Sc., Polytechnic of Wales, Professor in Electrical Engineering. Grigoryan, Anna, M.A., Azusa Pacific University, 2006, B. A., University of California Los Angeles, 2002, Senior Lecturer in Communication. Guefrachi, Hedi, M.A., University of Edinburgh, 1985, Diploma TEFL, University of Leeds, B.A., English, University of Tunis, 1981, Senior Lecturer in English. Gunaltun, Yves, Ph.D., M.S., Institute Natonal Polytechnique de Grenoble, 1981, 1979, Total Chair Professor, Professor in Mechanical Engineering. Gunister, Ebru, Ph.D., M.S., B.S., Istanbul Technical University, 2008, 2004, 1999, Assistant Professor in Mechanical Engineering. Gupta, Abhijeet Raj, Ph.D., B. Tech, 2010, 2006, University of Cambridge, United Kingdom, Assistant Professor in Chemical Engineering. Gyawali, Parshu Ram, Ph.D., M.A., Kent State University, 2009, 2005, M. Sc., Tribuhaven University, 1992, Assistant Professor in Physics. 160 H Hajsaleh, Jamal, Ph.D., M.Sc., University of North Texas, 1993, 1986, B. Sc., University of Jordan, 1984, Associate Professor in Physics. Harid, Noureddine, Ph.D., University of Wales, Cardiff UK, 1992, Ingenieur d’Etat, Polytechnic of Algiers, 1985, Associate Professor in Electrical Engineering. Haroun, Mohammed, Ph.D., Engineers Degree Petroleum Engineering, M.S., Environmental Engineering, M.S., Petroleum Engineering, 2009, 2007, 2008, 1998, University of Southern California, Associate Professor in Petroleum Engineering. Hasheem, Nabee, M.Sc., B. Sc., Bangalore University, 1983, 1981, Lecturer in Physics. Hassan, Asli, Ph.D., University of Maryland Baltimore County, 2011, M.A., University of Findlay, 1996, B.A., Marshall University, 1995, Assistant Professor in Communication. Hatakka, Mary, Ed. D., University of Exeter, 2014, M.A., B.A., University of Helsinki, 1991, 1983, Lecturer in Communication. Hayman, Mark, Ph.D., University of Warwick, 2000, M.A., B.A., University of Birmingham, 1990, 1975, Assistant Professor in History. Hjouj, Fawaz, Ph.D., Southern Illinois University, 2004, M.S., Al-Najah University, 1999, B. S., Yarmouk University, 1986, Assistant Professor in Mathematics. Hochstettler, Thomas, Ph.D., M.A., University of Michigan, 1980, 1970, B.A., Earlham College, 1969, President. Holcomb, Mark, Assistant Professor in Arts and Sciences. Holtby, Amy, M.Ed., B.A., University of Alberta, 2010, 2006, Lecturer in English. Hunaini, Enaam, M.A., Indiana University, 2002, B.A., Lebanese University in Beirut, 1988, Lecturer in English. I Islam, Md. Didarul, Ph.D., M.S., University of the Ryukyus, 2007, 2004, B. Sc., BIT Rajshahi, 1997, Assistant Professor in Mechanical Engineering. J Jabri-Pickett, Joud, M.A., University of Southern Queensland, 2009, B.A., University of Windsor, 1987, TEFL Certificate, 1990, Lecturer in English. 161 Jarrar, Firas, Ph.D., University of Kentucky, 2009, M. Sc., B. Sc., University of Jordan, 2005, 2001, Assistant Professor in Mechanical Engineering. Johnson, Pamela, M.S., University of Pennsylvania, 2008, B.A., William Paterson University, 1994, Lecturer in English. Jones, Ronald, M.A., University of New South Wales, 1996, B.A., University of Western Sydney, 1995, Lecturer in English. Jouini, Mohamed Soufiane, Ph.D., University of Bordeaux, 2009, M. Sc., M. Eng., ENSEEIHT University Toulouse, 2005, 2004, Assistant Professor in Mathematics. K Karanikolos, Georgios, Ph.D., M. Eng., Diploma, 2005, 2002, University at Buffalo, New York, USA, Assistant Professor in Chemical Engineering. Karki, Hamad, Ph.D., M.S., B. S., Tokyo University of Technology, 2008, 2005, 2003, Assistant Professor in Mechanical Engineering and Dean of Arts and Sciences. Khezzar, Lyes, Ph.D., Imperial College, 1987, M. Sc., University of London, 1983, B.S., University of Bradford, 1982, Professor in Mechanical Engineering and Deputy Chair of Mechanical Engineering. Kobrsi, Issam, Ph.D., Wayne State University, 2006, B. Sc., University of Western Ontario, 2000, Assistant Professor in Chemistry. Knight, Brian John, M.A., University of Reading, 1995, B.A., University of Bristol, 1987, Lecturer in English. Kokkalas, Sotirios, Ph.D., B. Sc., University of Patras, 2000, 1995, Associate Professor in Petroleum Geosciences. L Langille, Donald John, M.A., B.A., University of Oulu, 1993, 1980, Senior Lecturer in English. Lim, Hwee Ling, Ph.D., Murdoch University, 2007, M.A., National University of Singapore, 1994, Postgraduate Dip. Ed., National Institute of Educations-Nanyang Technological University, 1987, B.A., National University of Singapore, 1986, Associate Professor in Communication. Lokier, Stephen, Ph.D., University of London, 2000, B.S., Oxford Brookes University, 1996, Assistant Professor in Petroleum Geosciences. Lu, Jing, Ph.D., The University of Oklahoma, USA< 2008, M.S. Virginia Tech., USA, 1998, B.S., Southwest Petroleum, Assistant Professor in Petroleum Engineering. 162 M Martin, Neville, M.S., B.S., Newcastle Upon Tyne Polytechnic, 1984, 1983, Lecturer in Mathematics. McDermott, Mary, M.Sc., H. Dip Edc., University College Galway, 1983, 1981, Lecturer in Chemistry. Meribout, Mahmoud, Ph.D., M.S., University of Technology of Compiegne, 1995, 1991, B.S., University of Constantine, 1990, Associate Professor in Electrical Engineering. Midraj, Jessica, Ph.D., M.A., B.A., Indiana State University, 1999, 1998, 1996, Assistant Professor in Communication. Miller, Gary, Ph.D., University of New Brunswick, 1994, M.S., Queen’s University, 1990, Assistant Professor in Mathematics. Mittal, Vikas, Ph.D., Swiss Federal Institute of Technology, 2006, M.T., Indian Institute of Technology, 2001, B.T., Punjab Technical University, 2000, Associate Professor in Chemical Engineering. Mohammed, Jaby, Ph.D., University of Louisville, 2002, Assistant Professor in Arts and Sciences. Moore, David, M.A., B.A., University of Dublin, 2001, 1998, Lecturer in STPS and Director of Student Success Program. Morad, Sadoon, Ph.D., Uppsala University, Sweden, 1983, M.S., B.S., University of Baghdad, 1977, 1974, Professor in Petroleum Geosciences. Movsesian, Lala, M.A., Grad. Dip., University of Technology, Sydney, 2003, 2001, B.A., University of new South Wales, 2000, Assoc. Dip., St. George Institute of Educaiton, Sydney, 1987, Lecturer in English. Munster, Dominic, M.S., Cranfield University, 1999, B.S., University of Salford, 1998, Lecturer in Mathematics. Muyeen, S.M., Ph.D., M.S., Kitami Institute of Technology, 2008, 2005, B.S., Rajshahi University of Engineering and Technology, 2000, Associate Professor in Electrical Engineering. N Najaf-Zadeh, Reza, Ph.D., M.S., Lehigh University, 1987, 1980, B.S., Tehran University, 1977, Associate Professor in Physics. Nawrocki, Pawel, Ph.D., Institute of Fundamental Technological Research, 1988, M.S., Technical University of Lodz, 1980, Associate Professor in Petroleum Engineering and Chair of Petroleum Engineering. Nogueira, Ricardo, HDR, Ph.D., Paris VI University, 2004, M.Sc., Coppe/UFRJ, 1988, B.S., UFRJ, 1985, TOTAL Chair, GRC 163 Nunn, Roger, Ph.D., M.A., Reading University, 1996, 1989, Licentiate Diploma, Trinity College, London, 1983, Post Graduate Certificate in Education, King Alfred’s College, 1976, B.A., Cardiff University, 1975, Professor in Communication. O O’Kane, Rory, M.A., University of Ulster, 2001, M.A., University of Edinburgh, 1991, Lecturer in English. Olearski, Janet, M.A., Manchester Metropolitan University, 2012, M.A., University of London, 1986, P.G.C.E., University of London, 1982, M.A., University of Edinburgh, 1980, Senior Lecturer in English. Omer, Amani, Ph.D., University of Manchester, 2004, Assistant Professor in Arts and Sciences. Oral, Sevket Benhur, Ph.D., Iowa State University, 2007, Assistant Professor in Arts and Sciences. Osisanya, Samuel, Ph.D., M.S., The University of Texas at Austin, 1991, 1986, The University of Ibadan, 1976, Professor in Petroleum Engineering. Ozturk, Fahrettin, Ph.D., Rensselaer Polytechnic Institute, 2002, M.S., University of Pittsburgh, 1996, B.S., Selcuk University, 1992, Associate Professor in Mechanical Engineering. P Pasha Zaidi, Nausheen, M.A., Arizona State University, 2003, Assistant Professor in English. Peters, Cornelis, Ph.D., M.S., B.S., Delft University of Technology, 1986, 1978, 1975, Distinguished Professor in Chemical Engineering. Pillay, Avinash, Ph.D., University of London, 1982, M.Sc., B. Sc. (Hons), University of DurbanWestville, 1979, 1977, M.Sc., Wits University, 1987, Professor in Chemistry and Head of Chemistry. R Rahman, Md Motiur, Ph.D., M.E., University of New South Wales, 2002, 1994, B. Tech., Banaras Hindu University, 1985, Associate Professor in Petroleum Engineering. Randjelovic, Dragana, M. Sc., B. Architecture, University of Nis, Lecturer in Arts and Sciences. Reinalda, Donald, Ph.D., M. Sc., B. Sc., 1979, 1974, 1971, Leiden University, The Netherlands Shell Chaired Professor in Chemical Engineering & Gas Research Centre at PI. Rice, Erin Michala, M.S., Long Island University, 2007, M.A., New York University, 2004, B.A., Portland State University, 1996, Lecturer in English. Rindfleisch, William, M.A., San Francisco State University, 1984, B.A., University of Wisconsin – Madison, 1971, Senior Lecturer in English. 164 Riskus, A. Michael, Ed.D., Arizona State University, 2011, M.S., Hofstra University, 2003, B.A., University of Delaware, 2002, Senior Lecturer in English. Robinson, Lynne, M.A., Nottingham Trent University, 2005, B.A., South Bank University, 1993, Lecturer in English. Rodgers, Peter, Ph.D., B. Eng., University of Limerick, 2000, 1990, Professor in Mechanical Engineering. Rodrigues, Clarence, Ph.D., M.E., Texas A&M University, 1988, 1985, M. Tech., Insian Institute of Tech. (IIT), 1982, B.S., University of Bombay, 1980, Associate Professor in Mechanical Engineering, HSE Graduate Program Coordinator and PI-HSE Advisor (Acting.) Rostron, Paul, Ph.D., M.S., University of Northumbria (UK), 1996, M. Ed., Keele University, 1996, B. Sc., (Hons), Newcastle Polytechnic, 1990, Assistant Professor in Chemistry. Rostron, Rehana, M.S., University of Keele, 1996, B.S., University of Staffordshire, 1995, Lecturer in Physical Science. S Seela, Jeffrey, Ph.D., Indiana University, 1989, B.S., Iowa State University, 1983, Professor in Chemistry. Sheikh-Ahmad, Jamal, Ph.D., M. Sc., North Carolina State University, USA, 1993, 1998, Associate Professor in Mechanical Engineering. Shiryayev, Oleg, Ph.D., M.S., B.S., Wright State University, 2008, 2003, 2002, Assistant Professor in Mechanical Engineering. Shoukry, Ameera, M. Prof. Studies, Grad. Dip. Teaching, B.A., Univerity of Auckland, 2010, 2006, 2004, Lecturer in English. Simmons, Rodney, Ph.D., Texas A&S University, 1993, S.M., Harvard University, 1978, M.S., B.S., California State University Northridge, 1976, 1975, Associate Professor in Mechanical Engineering. Sinnokrot, Mutasem, Ph.D., M.S., Georgia Institute of Technology, 2004, 2000, B.S., University of Jordan, 1998, Assistant Professor in Chemistry. Small, James, M. Ed., Tech, University of Southern Queensland, 2007, Grad Dip., Macquarie University, 1988, B. S., Deakin University, 1981, Lecturer in General Studies. Steuber, Thomas, Ph.D., Dip., University of Cologne, 1989, 1987, Professor in Petroleum Geosciences and Chair of Petroleum Geosciences. Stitou, Samira, M.S., University of Toronto, 1998, M.S., Oklahoma State University, 1993, B.S., University of Central Oklahoma, 1988, Lecturer in Mathematics. 165 Srinivasakannan, Chandrasekar, Ph.D., Indian Institute of Technology, 1993, M.S., Coimbatore Institute of Technology, 1989, B.S., Annamalai University, 1987, Professor in Chemical Engineering. T Tao, Guo, Ph.D., Imperial College London, 1992, M.S., B.S., China University fo Petroleum, 1984, 1982,Professor in Petroleum Geosciences. Tatz, Sarah, M.A., The Ohio State University, 2006, B.A., Wellesley College, 2004, Lecturer in English. Taylorson, Jennifer, M. Lit., University of St. Andrews, 2012, B. Music, Royal Scottish Academy of Music and Drama, 2004, Lecturer in English. Tkach, Patreshia, MFA, Hamline University, 2005, B.S., St. Cloud State University, 1982, Lecturer in English. Toms, Colin, M.A., University of Reading, 1993, B. A., Thames Polytechnic, 1981, Senior Lecturer in English. Tran, Trung, Ph.D., B.S., University of Melbourne, 1999, 1994, Assistant Professor in Mathematics. U Umar, Abdullahi, Ph.D., University of St. Andrews, 1992, M. Sc., B.Sc., Ahmadu Bello University, 1986, 1983, Associate Professor in Mathematics. V Vahdati, Nader, Ph.D., University of California Davis, 1989, M.S., B.S., University of Portland, 1984, 1982, Associate Professor in Mechanical Engineering. Van Der Merwe, Riann, Assistant Professor in Arts and Sciences. Vega, Sandra, Ph.D., M.S., Stanford University, 204, 2000, B.S., Universidad Central de Venezuela, 1990, Assistant Professor in Petroleum Geosciences. Vesnaver, Aldo, Ph.D., M.S., University of Trieste, 1990, 1983, KADOC Chaired Professor in Petroleum Geosciences. Vukusic, Salafudin, Ph.D., University of Leeds, 2001, M.S., University of Manchester, 1997, B.S., University of Sussex, 1991, Assistant Professor in Chemistry. 166 W Wang, Kean, Ph.D., University of Queensland, 1998, M.S., Beijing University of Chemical Technology, 1989, B.S., Zhejiang University, 1984, Associate Professor in Chemical Engineering. Wang, Na, Lecturer in H&SS. Webb, Matthew, Ph.D., Australian National University, 2001, M.P.P.M., Monash University, 2010, M. Ed., Charles Sturt University, 2005, M.A., B.A., Victoria University of Wellington, 1996, 1991, Assistant Professor in Political Sciences. Wijeweera, Albert, Ph.D., University of Tennessee, 2004, M.A., Western Illinois University, 1999, B.A., University of Peradeniya, 1993, Associate Professor in Arts and Sciences. Williams, John, Ph.D., University of Exeter, 1979, M.A., Open University, 1993, Postgraduate Certificate in Technology Management, B.S., University of Exeter, 1974, Professor in Petroleum Engineering. Wyatt, Mark, Ph.D., University of Leeds, 2008, M.A., University of Edinburgh, 2000, Licentiate, Trinity College, 1997, Assistant Professor in Communication. Y Yit Fatt, Yap, Ph.D., Nanyang Technological University, 2008, M. Eng., B. Eng., University Teknologi Malaysia, 2002, 2000, Assistant Professor in Mechanical Engineering. Young, David Anthony, M.A., University of Limerick, 2001, B.A., National University of Ireland, 1996, Lecturer in English. Z Zhou, Bing,Ph.D., University of Adelaide, 1998, M.S., B.S., Chengdu University, 1989, 1982, Associate Professor in Petroleum Geosciences. 167 Campus Map The Petroleum Institute Campus Map k Ta e re r 8 Umm Al Nar Roundabout Asab P i ba Du Entrance Gate P 9 H H 5 26 Delma 25 Jarneen 21 H 24 Abalbokhoush 32 Budana 22 6 H H 20 4 23Al Bundouq 15 23 P H Entrance Gate 3 31Heil 2 Takreer Research Center H 13 21 Umaldalkh H PI Research Center (under construction) 1 Entrance Gate H 11 Satah P Abu Dhabi 1 168 10 200 meter 0 Zarkuh (AUP, Classrooms, Cafeteria, Student Support, Student Lounge) 2 Bu’Hasa 3 Ruwais (EE, ME, PE, & PG, Classrooms, Labs, Faculty Offices) (A&S, CE, Classrooms, Labs, Faculty Offices, Athletics, Student Affairs, SOS, Dietician) 9 Football Fields 10 Satah (Student Center, Cafeteria) 11 Student Dorm, Resident Life, Learning Center 13 HEIL B31 (Student Clubs, FMS Offices, Printing Center) 4 Umm Shaif (Faculty Offices, Classroom) 15 BU DANA B32 (Student Dorm, Laundry) 5 Habshan 20 C-Store - OASIS 6 Arzanah 21 Block-C (Graduate Student) 8 ASAB (Sports Hall, Recreation & Fitness Center) 22 HSE Lab, Solar Car Workshop 23 Old ATI (ME Workshop, Graduate Student) (Library & Administration) (WiSE Facilities) Clinic Mosque P Parking Restaurant H Student Dorm 169 The Petroleum Institute PO Box 2533, Abu Dhabi, United Arab Emirate t: +971 2 607 5100 f: +971 2 607 5200 www.pi.ac.ae 170