Photonics in Germany 2011
Transcription
Photonics in Germany 2011
Optische Technologien in Deutschland Photonics in Germany 2011 Publisher / Herausgeber trias Consult Johannes Lüders Crellestraße 31 D – 10827 Berlin Phone +49 (0)30 - 781 11 52 Mail trias-consult@gmx.de Web www.optical-technologies-in-germany.de www.microsystems-technology-in-germany.de Photo Credits / Bildnachweis Title Photo / Titelfoto Frank Brückner, Berlin Page / Seite S 3 OSRAM GmbH S 8 TRUMPF GmbH & Co. KG S 20 OHARA GmbH S 58 Fraunhofer IOF S 72 Fraunhofer IOF S 115 Lumino Licht Elektronik GmbH Layout Uta Eickworth, Berlin Phone +49 (0)30 - 917 08 117 Mail eickworth@onlinehome.de Web www.designcircle-berlin.de Printing / Druck GCC Grafisches Centrum Cuno, Calbe 2011, Printed in Germany ISSN 2191-7191 (Printausgabe) Look Sharp! PIFOC Travel Ranges up to 1 mm Resolution <1 nm Linearity to 0.03 % ® – HIGH DYNAMICS PIEZO NANOFOCUSING SYSTEMS These extremely precise focusing systems are unique for their extra-long travel ranges and sub-nanometer resolution. With their minimal settling times and outstanding focus stability, they are winning over users in Life Sciences and Metrology. You, too, can look sharp: info@pi.ws · www.pi.ws Physik Instrumente (PI) GmbH & Co. KG · Tel. +49-721-4846-0 PIEZO NANO POSITIONING pi_100846_pifoc_175x58_en.indd 1 09.09.10 13:15 4 Table of Contents 28 Preface Grußwort 6 Prof. Dr. Annette Schavan Federal Minister for Education and Research Bundesministerin für Bildung und Forschung 30 32 News Ways in Photonics Neue Wege in den Optischen Technologien 10 12 14 16 18 Peter Leibinger Spokesperson for the "Photonik 2020" Initiative: Light is the Future – the "Photonik 2020" Initiative Frank Schlie-Roosen Federal Ministry of Education and Research: BMBF LED Lead Market Initiative in Germany Evelyn Moeck Germany Trade & Invest: Germany – Where Expanding Markets and Next Generation Technologies Meet Birgit Ladwig SPECTARIS e. V.: Hightech and Innovation in German Small and Medium-sized Companies Gerhard Hein, VDMA: Why are Photonics Companies Investing in Germany? New Dimensions and Current Solutions in Photonics Neue Dimensionen und aktuelle Lösungen in den Optischen Technologien 22 24 26 Production and Mechanical Engineering Reinhart Poprawe, Ingomar Kelbassa Fraunhofer ILT: Tailored Light for Next Generation Products and Emerging Applications Klaus Stolberg, Andreas Büchel Jenoptik Laser GmbH: Tools of Light Andreas Tünnermann Fraunhofer IOF: Challenges in Modern Optics 34 36 38 40 42 44 46 48 Life Sciences Markus Sticker Carl Zeiss MicroImaging GmbH: Optical Imaging in Life Sciences and Medical Diagnostics Klaus Irion Karl Storz GmbH & Co.KG: Endoscopic Imaging and Treatment Peter Schubert R-Biopharm AG: Analytical Applications in Life Sciences and Diagnostics Communication and Information Jörg-Peter Elbers ADVA AG: Fast Communication with Light – Photonics for the Networked Society Hans-Joachim Grallert Fraunhofer HHI: Convergence? – Microphotonics as the Successor Technology to Microelectronics? Markus Ehbrecht, Frank Guse QIOPTIQ Photonics GmbH & Co KG: Image Acquisition and Projection Techniques: Modern Head-up Displays for the Automotive Industry Lighting and Energy Berit Wessler OSRAM GmbH: Solid State Lighting – the Light of the Future Andreas Bett Fraunhofer ISE: III-V Multi-Junction Solar Cells and Concentrating Optics Emerging Technologies Dieter Meschede Universität Bonn: Quantum Optics – Optics and Photonics at the Doorsill of Quantum Technology Martin Wegener Karlsruhe Institute of Technology: Photonic Metamaterials: Optics Starts Walking on Two Feet Marc Vrakking, Max-Born-Institut: Ultrashort Lasers that Probe Deep inside Matter 5 Inhaltsverzeichnis 50 52 54 56 Ruth Houbertz-Krauß Fraunhofer ISC: Ultra-short Laser Pulses for 3D Patterning – Enabler for Optical and Life Science Applications Organic Electronics Michael Kröger InnovationLab GmbH: Forum Organic Electronics: Innovation and Growth in a Green Environment Walter Fix, Klaus Schmidt PolyIC GmbH & Co.KG: Printed Electronics - Process and Products Christian May Fraunhofer IPMS: Roll to Roll Fabrication of OLED Lighting Devices Results and Services from Research Clusters and Institutions Ergebnisse und Dienste von Clustern und Einrichtungen der Forschung 60 62 64 66 67 68 69 70 71 TSB Innovationsagentur Berlin GmbH Fraunhofer IOSB Fraunhofer IOF Technische Universität Ilmenau Fraunhofer HHI Fraunhofer IWS Fraunhofer IWS, Roth & Rau Microsystems GmbH PhotonikBB Fraunhofer IAP 78 79 80 81 82 83 84 Omicron-Laserage Laserprodukte GmbH TOPTICA Photonics AG Northrop Grumman LITEF GmbH LASOS Lasertechnik GmbH HighFinesse GmbH Sacher Lasertechnik GmbH LUMERA LASER GmbH 85 86 88 89 90 92 93 Components Micro-Hybrid Electronic GmbH QIOPTIQ Advanced Optics SCHOTT AG II-VI Deutschland GmbH FRANK OPTIC PRODUCTS GmbH eagleyard Photonics GmbH Vertilas GmbH 94 95 Data Transmission ADVA AG Optical Networking u2t Photonics AG 96 97 98 101 102 104 106 107 108 109 110 112 113 High Precision Solutions and Equipments JENOPTIK AG ZygoLOT GmbH Leica Microsystems GmbH tec5 AG Sypro Optics GmbH SCHÖLLY FIBEROPTIC GMBH Häcker Automation GmbH OWIS GmbH Physik Instrumente (PI) GmbH & Co. KG LT Ultra-Precision Technology GmbH LEYBOLD OPTICS GmbH Vistec Electron Beam Lithography Group Berliner Glas KGaA Herbert Kubatz GmbH & Co. Innovations and Competencies in Industry Innovationen und Kompetenzen aus Unternehmen Markets and Networks 74 75 Laser, Optics Design LightTrans GmbH JCMwave GmbH 76 77 Systems LIMO Lissotschenko Mikrooptik GmbH ROFIN-SINAR Laser GmbH 116 118 German Society of Applied Optics (DGaO) LASER World of PHOTONICS 6 Preface Optical instruments have changed the world. The telescope enabled researchers to describe the earth as a sphere in an endless universe; the microscope made microbiology possible. Electric light replaced flames, X-rays revolutionized medicine. And the laser, invented in 1960 without a specific application in mind, conquered factories as a universal tool and has since become the backbone of the modern communication society. The utilization of the photon has led to the development of a highly-specialized industry in which Germany is the world leader. The turnover of optical technologies production in Germany was about 20 billion euros last year. However, we cannot stop here: we are facing increasingly fierce competition for market leadership, talent and technologies. Education, research and innovation are becoming increasingly important. They are the basis for economic growth and social prosperity. In order to maintain and enhance our excellent position in this globally competitive market, we need to invest now – in the training of skilled labour, in excellent research and development, and in structures that promote innovation. Science, industry and politics will have to close ranks. Prof. Dr. Annette Schavan, Federal Minister of Education and Research Bundesministerin für Bildung und Forschung This is where Germany's High-Tech Strategy 2020 comes in. It aims to further improve the conditions for innovations and create lead markets in fields in which there is high societal demand, such as climate and energy, health and nutrition, mobility, security and communication. The consistent utilization of light as a resource will make important contributions to meeting these challenges – keeping people healthy, using resources sustainably, and generating and using energy in an efficient way. We want to use the full potential of photonics to strengthen our country and make it more competitive on an international scale. We are aware that we are not only responsible for the here and now, but also for the future. Prof. Dr Annette Schavan, MdB Federal Minister of Education and Research 7 Grußwort Optische Instrumente haben die Welt verändert. Das Teleskop erlaubte es den Forschern, die Erde als eine Kugel in einem unendlichen Universum zu beschreiben, das Mikroskop machte die Mikrobiologie möglich. Elektrisches Licht löste die Flamme ab, Röntgenstrahlen revolutionierten die Medizin. Und der Laser, 1960 noch eine Erfindung auf der Suche nach einer Anwendung, eroberte als Universalwerkzeug die Fabrikhallen; mittlerweile ist er das Rückgrat der modernen Kommunikationsgesellschaft. Mit der Nutzbarmachung des Photons hat sich in Deutschland ein hoch spezialisierter Industrie- und Wirtschaftszweig entwickelt, der international an der Spitze steht. Allein der Produktionsumsatz für Optische Technologien am Standort Deutschland betrug im vergangenen Jahr rund 20 Milliarden Euro. Doch wir dürfen nicht stehenbleiben: Der Wettbewerb um Marktführerschaft, Talente und Technologien nimmt zu. Bildung, Forschung und Innovation werden immer wichtiger. Sie legen die Grundlage für wirtschaftliches Wachstum und sozialen Wohlstand. Um unsere hervorragende Position im globalen Wettbewerb zu halten und auszubauen, müssen wir jetzt investieren – in die Ausbildung von Fachkräften, in exzellente Forschung und Entwicklung und in innovations- fördernde Strukturen. Wissenschaft, Wirtschaft und Politik müssen dafür gemeinsam voranschreiten. An dieser Stelle setzt die Hightech-Strategie 2020 an. Sie zielt darauf ab, die Rahmenbedingungen für Neuerungen weiter zu verbessern und Leitmärkte in den gesellschaftlichen Bedarfsfeldern Klima und Energie, Gesundheit und Ernährung, Mobilität, Sicherheit und Kommunikation zu schaffen. Zur Lösung dieser Herausforderungen wird die konsequente Nutzung des Rohstoffs Licht wichtige Beiträge leisten – wenn es um die Erhaltung der Gesundheit geht genauso wie bei der nachhaltigen Nutzung von Ressourcen und der effizienteren Erzeugung und Nutzung von Energie. Wir wollen das Potenzial der Photonik nutzen, um unser Land für den globalen Wettbewerb zu stärken. Denn wir haben nicht nur Verantwortung für das Hier und Jetzt, sondern auch für das Morgen. Prof. Dr. Annette Schavan, MdB Bundesministerin für Bildung und Forschung New Ways in Photonics NEW WAYS IN PHOTONICS 10 Light is the Future – the "Photonik 2020" Initiative Light is one of the key technologies for the German economy. In many areas of photonics, German companies are already global market leaders at the forefront of technology. This success is founded on longstanding collaboration between industry, science and politics. In the future, it’s our desire to not only maintain our leading position but to continue to build on it. Germany aims to remain a leader in optical technologies, as these are key drivers of growth and innovation. Mastering photon technology is essential if Germany is to have a principal role in areas such as climate protection, mobility issues, technologies required for modern production facilities, development and distribution of information, and medical engineering. In order to achieve this, we will continue our efforts to develop and strengthen the cooperation between industry, science and politics. As part of the "Photonik 2020" initiative, in 2009 three industry associations, VDMA (German Engineering Federation), ZVEI (German Electrical and Electronic Manufacturers Association) and SPECTARIS (German High-Tech Industry Association) joined forces with research institutions, small and medium sized enterprises and large companies to form the new "photonics industry." The goal was to continue building on Germany's leading role in light- Figure 1: The use of lasers for cutting, welding and labeling has become an integral feature of production plants around the world. based solutions in the areas of production and engineering, life science and medical engineering, communication and information, and energy and the environment. To this end, the German photonics industry, which currently employs around 120,000 people, will invest up to 20 billion Euros in research and development over the next ten years. This equates to around 10% of total sales revenue. Germany's politicians are also aware of the importance of photonics and are supporting applied research in optical technologies. The Federal Ministry of Education and Research's current funding program "Optical Technologies – Made in Germany" will run until 2012. Meanwhile, the "Photonik 2020" initiative launched its strategy development process at the end of March 2010 in Berlin, where around 300 experts in optical technologies from science and industry convened, and has set the goal of defining guidelines to shape the future of optical technologies in Germany. Our support is targeted toward those research projects that have the greatest potential for impacting the future. Apart from this, the principal reason for the success of the German photonics industry is that Germany offers prime Figure 2: LED and OLED semiconductor technologies will bring about a revolution in light technology. NEW WAYS IN PHOTONICS 11 Peter Leibinger, spokesperson for the "Photonik 2020" initiative and Vice-Chairman of the Management Board at TRUMPF conditions as a location for optical technologies. We have succeeded in establishing the entire innovation and value chain at a leading international level. The companies, suppliers and research institutions in Germany work together in a tightly integrated network, and outstanding standards of excellence are achieved in research and development. Light-based solutions offered by the German photonics industry are as fascinating as they are diverse. Take lasers, for example: The use of lasers for cutting, welding and labeling has become an integral feature of production plants around the world. Yet despite the advancement of laser technology in the industrial processing of materials, these are still the pioneer days. Half a century after its invention, the laser still has its best years ahead of it – and the photon is the tool of the future. In medicine, the photon has the potential for a paradigm shift away from the treatment of diseases and toward preventing them in the first place. The foundation for this will be laid as a result of improved understanding of life processes, from the cellular right down to the molecular level, gained by means of optical methods. Light is also the number one driver of innovation in telecommunications and information technology. It is already the case that no telephone or Internet calls can be made without light. As far as the visualization of data in information technology is concerned, the future will bring many new display technologies offering unprecedented levels of brilliance. LED and OLED semiconductor technologies will bring about a revolution in light technology. They meet the technical requirements of our time – high energy efficiency, long service life and completely new design possibilities – in a way that no other light source does. Also, photovoltaics, the energy source of the future, is only just beginning to reveal its potential. Figure 3: Half a century after its invention, the photon is the tool of the future. Figure 4: Photovoltaics, the energy source of the future, is only just beginning to reveal its potential. Light is the future – and for the German photonics industry the future looks brilliant. New developments in optical technologies will shape the decades to come. Germany will be at the center, leading these developments rather than merely on the sidelines, thanks to the joint "Photonik 2020" initiative bringing industry, science and politics together. TRUMPF GmbH + Co. KG Johann-Maus-Straße 2 D – 71254 Ditzingen Phone +49 (0)7156 - 303 - 0 Mail info@trumpf.com Web www.trumpf.com NEW WAYS IN PHOTONICS 12 BMBF LED Lead Market Initiative in Germany Dr. Frank Schlie-Roosen The Federal Ministry of Education and Research (BMBF) supports collaborative research projects at the interface between science and industry. This type of research funding has also been successful in the development of industrial laser applications – so successful that German companies and institutes working in this area are now internationally renowned and highly sought-after. The area of incoherent light is also benefiting from cooperative activities between science and industry. The direct electronic emission of light – the light-emitting diode – is expected to conquer more and more areas of application and become the most important source of light in coming years. Its advantages include superior energy efficiency, simple tuning and control, low-priced production and regulated disposal. German scientists and companies were pioneers in making LED technology ready for use in the area of general lighting. But innovations are not just about facts and data. The success or failure of new technologies depends on a large number of individual decisions in individual situations. And people tend to base such decisions more on habit than on technological facts, which they cannot verify themselves. Producers, retailers and consumers have become accustomed to certain technologies, particularly if the technology in question has not changed for many decades, as is the case with light technology. In the area of light, examples of these entrenched ways of thinking include measuring light output in watts, the price ranges that are considered "acceptable", the cognitive model of lamp and bulb, and the existence of separate sales channels for different light technologies. New and different technologies give rise to uncertainty, to the extent that people sometimes opt for an outdated solution just because it is a known quantity. Economists refer to this phenomenon as “path dependence”, which can sometimes even cause market failure. It means that new technologies are sometimes not applied at all – or applied much later than would have been technologically possible. The BMBF conducted talks with experts in late 2008 and concluded that in Germany, path dependence might lead to market failure particularly in the building illumination and outdoor lighting sectors. These market segments are characterized by long investment cycles and autonomous, decentralized decisions taken by a large number of different stakeholders, many of them in the public sector. The risk involved in an investment decision is an important factor in such markets, and these considerations are often an argument against new LED technology. The LED Lead Market Initiative was launched by the BMBF at the beginning of 2009 with the aim of making the risks of LED technology easier to calculate: • by developing neutral, scientifically sound measuring and characterisation • by supporting and documenting manufacturer-independent best practice examples • by developing adapted business and contract models for financing LED projects and risk management Key stakeholders active in the fields of indoor and outdoor lighting are involved in the LED Lead Market Initiative (including ZVEI, Lichttechnische Gesellschaft, Verband Kommunaler Unternehmen, ÖPP/Partner Deutschland, and the Climate Change Finance Forum). Other partners, including lighting technology manufacturers, are involved in the working groups. The LED Lead Market Initiative has thus become the national platform on which stakeholders discuss problems related to LED use in general lighting and promote the development of solutions. The design of neutral measuring processes is needed for potential insurance solutions for LED projects and for the development of a seal of quality in the area of lighting technology that will make it easier for consumers and purchasers to decide in favour of quality. Because such a seal of quality can only be successful if introduced at a European level, the BMBF and the partners in the LED Lead Market Initiative have initiated a dialogue with the European Commission. The BMBF organized the “Kommunen in neuem Licht" (local communities in a New Light) competition in 2010, NEW WAYS IN PHOTONICS 13 which raised awareness of the issue among public-sector decision-makers. More than 140 proposals were submitted and evaluated by a jury. As a result, 10 local LED projects are being realized and documented so that real problems and solutions can be investigated and assessed for followup projects. LED technology is still young and new. It only became evident a few years ago that this technology was suitable for lighting purposes. Global competition in this area is only just beginning. This means that success no longer depends on research activities. The market will decide which areas will see investments and which technologies will assert themselves. Or rather, the markets will decide, because demand for LED technology comes from a number of different market segments. In China, for example, huge areas are equipped with central electrical lighting for the first time, so no allowances need to be made for existing systems. In Africa and India, the main challenge is providing lighting in areas that are not connected to the grid. This requires systems with integrated power generation and storage, for which a sales and maintenance structure needs to be developed. In the USA and in Europe, where electric light has been used in buildings since 1930/1940 and in public spaces since 1960/70, replacement solutions (retrofits) play a particularly important role in the market launch of LED technology. The introduction of LED technology for general lighting will trigger enormous investments across the world. According to market researchers, production capacities for LEDs would have to grow by an average of 30% p.a. over the next 20 years for the lighting market to be fully exploited. Significant further investments can be expected in the area of application and in other, completely new lighting markets, such as LED furniture and textiles or lighting control via mobile phones. Because German and European companies are world leaders in the field of light technology, it is important to apply the new LED technology here as quickly as possible. This is the only way to ensure that German manufacturers can successfully reposition themselves during the technological transition and that the environmental advantages of this technology can be applied both quickly and effectively. With its LED Lead Market Initiative, the BMBF wants to contribute to this development and show that the Federal Government’s High-Tech Strategy goes beyond the research stage and shapes the entire innovation process. MinR. Dr. Frank Schlie-Roosen Bundesministerium für Bildung und Forschung Referat 513 Heinemannstrasse 2 D – 53175 Bonn Phone +49(0)228 - 9957-3259 Mail frank.schlie-roosen@bmbf.bund.de NEW WAYS IN PHOTONICS 14 Germany – Where Expanding Markets and Next Generation Technologies Meet Germany can proudly claim to be Europe's leading nation in photonics and an optimal production and investment location. Employing a workforce of almost 120,000 people, the photonics industry in Germany is in excellent shape. Around 10 percent of turnover is reinvested in research and development, with around half of that turnover generated by new products. Total sector turnover in 2010 is expected to grow to EUR 21.2 billion – up 15 percent from the previous year. Germany enjoys a reputation as an export nation – this is also the case for products in photonics. Exports increased by 16 percent in 2009 (EUR 14.4 billion), representing around two-thirds of overall turnover. As for imports, Asian Evelyn Moeck Mechanical and Electronic Technologies Germany Trade and Invest GmbH, Berlin suppliers dominate imports to Germany with 43 percent, followed by imports from EU countries and North America. Photonics products “Made in Germany” benefit from a healthy international reputation thanks to the country’s focus on high quality engineering. The industry landscape consists of more than 1,000 companies; typically small and medium-sized entities. The specific structure of the photonics industry makes a strong network imperative. In Germany, significant efforts are made to ensure close contact between industry and research, politics and industry, customers and suppliers, as well as between competitors. International companies are welcomed at these networks to link expertise and markets around the world. Optoelectronics technology is equipping cars with "active" safety features to prevent accidents. Source: Volvo. NEW WAYS IN PHOTONICS 15 Investment Opportunities in Photonics in Germany Photonics applications are ubiquitous and include everything from products used in everyday life to the most highly advanced scientific operations. Areas of application that have been identified as pivotal in Germany include information and telecommunication, health sector and life sciences, illumination and energy, industrial production, optical sensor technology, and manufacturing of optical components and systems. Over the last thirty years, the use of optical components has grown to the point that the global telecommunications market has come to depend on this key technology to link all of its backbone services as well as link into the access network. Because of this dependence on fiber optical components and optical systems, photonics is considered an enabling technology. German companies play a major role in this market. The expansion of high-speed communication worldwide has provided many opportunities for the development of associated component technologies. Photonics solutions can make networks more transparent, dynamic, faster and environmentally friendly. New technologies are also revolutionizing health care industry methods for predicting, preventing and treating illnesses. Photonic solutions and applications have an important role to play. As Europe’s most populous country, Germany has the largest health care market in Europe, and an aging population that will demand new and better products. Maintaining Germany's high level of health care quality, while at the same time keeping the healthcare system affordable, is a specific goal of German health policy. Innovative products can help contribute to achieving this goal. Microscopes and endoscopes help to understand cell processes, tissues and model organisms, as well as supporting the development of drugs specific to the patient. The lighting industry is the biggest beneficiary of photonics solutions. The future prospects of this segment depend on using efficient light which could help reduce CO2 emissions in Germany by approximately six million tons. The year 2012 will mark the end of conventional light-bulb production in Europe; ushering in a new era of flexible photonic light sources – such as LEDs – that are an essential element of future energy savings. Current forecasts predict that every third light source will be an LED by 2025. The greatest growth potential exists in the auto industry, general lighting, electric equipment, signage and displays. The high level of consumer acceptance towards energy efficient lighting alternatives proves Germany as the European entry market par excellence. The photovoltaic market is another important optical technologies application segment. The total installed solar energy output in Germany will increase tenfold by the year 2017. Germany is the largest photovoltaic market worldwide and enjoys an unmatched international reputation. In New optical technologies for enhanced visualization for clinicians and surgeons . Source: Carl Zeiss. order to maintain this market leader position, all photovoltaic manufacturers are engaged in increasing the efficiency of their products and the productivity of their processes. For their next-generation production lines, non-contact processing equipment- which prioritizes laser-based processing – is considered essential. Photovoltaic industry R&D investments of around EUR 1 billion are planned through 2013. Cooperation projects with industry participants and institutes across this market segment create new investment opportunities for international investors. Incentives in the Photonics Industry in Germany Germany offers numerous incentives for all investors – regardless of whether they are from Germany or not. There is a large selection of programs available designed to support a wide variety of business activities at different stages of the investment process. Support ranges from cash incentives for the reimbursement of direct investment costs to incentives for labor and R&D. Most notable for the photonics industry is the "Optical Technologies" framework program provided by the federal government. Germany Trade and Invest and its services Germany Trade & Invest is the foreign trade and inward investment agency of the Federal Republic of Germany. Its mission is to promote Germany as a location for industrial and technological investments and to identify investors for the German market. With our team of industry experts, incentive specialists and other investment related services we assist companies in setting up business operations in Germany. All services are treated with the utmost confidentiality and provided free of charge. Germany Trade and Invest GmbH Friedrichstraße 60 D – 10117 Berlin Phone +49(0) 30 - 200 099 - 0 Fax +49(0) 30 - 200 099 - 111 Mail evelyn.moeck@gtai.com Web www.gtai.com NEW WAYS IN PHOTONICS 16 Hightech and Innovation in German Small and Medium-sized Companies Birgit Ladwig Head of Photonics + Precision Technology / Analytical, Bio and Laboratory Technology SPECTARIS e.V. Without a doubt, photonics is one of the key industries of the future for the German economy, and this notwithstanding the fact that the importance of photonics is not widely acknowledged by the general public. Nevertheless, photonics products can be found in nearly all spheres of life and the photonics industry remains highly innovative and experiences above average growth rates and employs around 120,000 people. As a key enabling technology, photonics is at home in a broad range of industries like photovoltaics, production and semiconductor technologies and life sciences. With an impressive export ratio of almost 68 percent, the German photonics industry has proven to be internationally competitive. German companies have already secured a large piece of the future photonics market and currently hold a nine percent share of an industry with an annual turnover worth of around 256 billion Euros worldwide. Although Asian countries and the US share a larger proportion of the total value, German producers have been able to establish themselves successfully in a number of niche markets. This is especially true for innovation-intensive high-tech areas and for products that require very high precision and quality values. Companies such as these have not been focusing as much on the cost-driven mass production of optical appliances. In the future, it will be particularly important for small and medium-sized companies to be at the cutting edge of innovation and uphold their technological leadership. In many areas, German companies are already at the vanguard of technological development and it is important for SPECTARIS to further promote this development. For German producers, there is no alternative to innovation. The German photonics industry always has to remain one step ahead of its competitors in Asia and the US. Innovation is the key to this position. If the German photonics industry can maintain its present market position, it will almost certainly contribute substantially to broader German economic growth. This will undoubtedly create new growth areas for the industry in addition to the already established photonics base industries. As the year 2009 has demonstrated, international competitiveness through new innovative growth industries is of crucial importance for the export-driven German economy. Project Grants: A Success Story! For the high-tech industry in Germany, project grants have become indispensable for R & D and have made a significant contribution to the continuing status of Germany as a technological innovator and leader. Each year more than five billion Euros of capital investment grants are awarded under the auspices of the Federal Project Promotion and Grant Program. It is important to note the extent of public leverage in the funding equation: for each publicly funded euro, two euros from private sources are added. Significantly, according to a study by the Center for European Economic Research, no windfall gains were observed in relation to the Project Grant Program. The photonics industry has benefited enormously from the Federal Project Grant Program. The grants have been an important factor in the industry’s marked turnover growth and increase in employee numbers over the past few years. The figures speak for themselves: In 2005, around 100,000 employees produced a turnover of circa 16.3 billion Euros. In 2008 however, turnover and employee numbers had climbed to 22 billion Euros and 120,000 respectively. The advantages of project grants reach far beyond immediately striking financial data. Professional networks and connections built-up during projects supported by grants remain intact even after the grants have expired. The results are impressive – follow-up projects arise, new partnerships are created and research teams continue to cooperate. These partnerships further support the recruitment and training of skilled employees, who benefit from the expertise extended networking possibilities provide. The photonics industry has become dependent on the close vertical networks developed between producers and users thanks to the Federal Project Grant Program. Crucially, the program has also helped to extend these networks to incorporate universities and other scientific institutions. NEW WAYS IN PHOTONICS 17 Sources: OHARA GmbH Heraeus Noblelight GmbH Heraeus Noblelight GmbH Carl Zeiss AG Spectra Physics GmbH Schott AG Future Potentials and Markets Photons instead of electrons – scientists entitle the 21st century as „Century of Light“. A current essay by Fraunhofer Institute for Applied Optics and Precision Engineering (IOF) shows how the German Photonics industry can contribute to solving global challenges. Photonics will be of fundamental importance for the technological advancement of the following four areas: • Information and communication • Health and Nutrition • Energy and Environment • Security and Mobility The essay states that the photonics industry is very well positioned in terms of technology and produces essential future instruments for markets with tremendously increasing economic importance since it is an enabling technology for many industries. As an overall conclusion, it can be stated that the above-average innovation potential of the photonics sector makes it a key industry for economic growth in Germany and Europe. Using this innovation potential was also made possible by project grants, which were an important instrument to develop a global market leadership. After a short-term slowdown during the economic crisis, this highly future-oriented sector is in full recovery, with great potential for future growth. SPECTARIS German Industry Association for Optical, Medical and Mechatronical Technologies Deutscher Industrieverband für optische, medizinische und mechatronische Technologien e.V. Birgit Ladwig Werderscher Markt 15 D – 10117 Berlin Phone +49(0)30 - 4140 21 - 31 Fax +49(0)30 - 4140 21 - 33 Mail ladwig@spectaris.de Web www.spectaris.de NEW WAYS IN PHOTONICS 18 Why Are Photonics Companies Investing in Germany? Gerhard Hein, Managing Director of the VDMA-Division “Lasers and Laser Systems for Material Processing” and Head of the VDMA-Forum “Photonics” The short answer boils down to four factors: • Because business, science and research policy in Germany have leveraged exemplary collaboration and joint efforts which have established global excellence in the field of optical technologies. • Because Germany’s professional education and institutional landscape guarantee adequate availability of what is the sine qua non asset in the innovation process and the production environment: highly qualified personnel. • Because Germany’s value generation chain is an outstanding example of a seamless, closed-loop system in which the supplier network ensures high reliability. • And because German economic and labour market policy provides effective instruments for retaining core staff during periods of crisis – instruments that the rest of the world envies. The clear messages that this sends to companies seeking to invest here are examined in greater detail below, also drawing in particular on examples from the German laser industry. The aforementioned excellence in optical technologies opens up huge opportunities in manufacturing engineering applications, for example, but just as clearly in connection with environmental protection, energy efficiency and the conservation of natural resources, healthcare and state-of-the-art communications. And ultimately in the context of opening up photonics-based mass markets through customised materials or organic electronics. As a manu- Sources: ROFIN-SINAR LIMO-Lissotschenko facturing location, Germany needs more than just to have new products developed here. Rather, we have to ensure that these products can also continue to be produced right here in this country. The fundamental principle is to provide suitable manufacturing technologies and production engineering clusters that work efficiently together and attract high-profile applications. One benchmark of particularly current relevance for the outstanding cooperation between business – ranging from classic medium-size companies to major global corporations – and science and research policy is the ongoing 2nd Agenda Process Photonics 2020, which no longer exclusively involves laser technology, for example – although the special emphasis obviously does focus there – but also treats separate technology issues or the timely development of specific application areas. An overall strategy for Germany is emerging! It will lay out how the key photonics technologies can be applied even more effectively to solve the urgent issues of vital importance to the future of society. In this context, particularly emphasis is also being placed on the opportunity for Germany to assume a pioneering role with respect to the link between environmental protection and cost-effective production. State-of-the-art laser technology will have more and more answers at the ready for megatrends such as energy efficiency and e-mobility. Innovative laser sources will prove that the resulting products such as electric vehicles, high-performance batteries, fuel cells or solar panels can be produced profitably in Germany. The entire agenda process is being led by the LPKF NEW WAYS IN PHOTONICS 19 Laser und Lasersysteme für die Materialbearbeitung industry, and most of the experts involved come from the field of photonics or from business sectors that make use of photonics. That means that the market is uncompromisingly defining innovation! Not least through strategically and regionally targeted funding measures, Germany has established a densely woven institutional landscape with a functionally optimised structure. Not only does it conduct essential basic research and make fundamental contract research contributions under the guise of “outsourced development departments”, but it also assumes a key role in the specialised training of experts and managers. Companies recruiting new staff logically establish bonds through the support of functionally focussed Masters level studies, scholarships and the provision of work-study positions. This is the only way to maintain outstanding innovative capabilities, which are borne out by a 40% share of university degree holders in the laser technology sector – a sector that currently invests 14% of its earnings in R&D activities. Optical technologies generate up to 80% of their earnings through exports, but also purchase material from suppliers at a rate of nearly 50% of turnover – more than 80% of which involves sourcing from within Germany. This clearly testifies to the country’s uniquely seamless value generation chain and high supply reliability. In 2009, and with carryover into 2010, beside the agenda process compounded by high planning insecurities, viable paths out of the global financial and economic crisis had to be found. Maintaining a decisive orientation TRUMPF towards the future despite extremely difficult economic conditions proved to be a challenge of the first order! Through the responsibly handled application of labour market policy instruments – such as the flexibilisation of working hours negotiated fairly with the collective wage agreement parties and the German regulations on short-time working arrangements – the industry was able to implement a rather “soft” adjustment of the workforce levels in the photonics sector and to maintain strong and qualified personnel coverage for the coming economic upswing. At its historical peak in 2008, the workforce numbered 110,000 people in all. That figure fell by less than 7% during the crisis in 2009. From 2005 to 2008, the number of employees in the industry had increased by about 27%. So optical technologies also appear to be a veritable “job machine” during economic growth phases. Taken together, these facts constitute persuasive arguments for successful entrepreneurship in photonics and for the reality-based formulation of economic and labour market policy! VDMA - Arbeitsgemeinschaft Laser für die Materialbearbeitung Forum Photonik im VDMA Corneliusstraße 4 D – 60325 Frankfurt am Main Phone +49(0) 69 - 756081 - 43 Fax +49(0) 69 - 756081 - 11 E-Mail g.hein@vdw.de Web www.vdma.org/laser TRUMPF TRUMPF New Dimensions and Current Solutions in Photonics NEW DIMENSIONS AND CURRENT SOLUTIONS IN PHOTONICS 22 Tailored Light for Next Generation Products and Emerging Applications Authors: Akad. Oberrat Dr.-Ing. Ingomar Kelbassa Prof. Dr. rer. nat. Reinhart Poprawe M.A. Prof. Dr. rer. nat. Reinhart Poprawe M.A. Introduction When the Laser was demonstrated for the first time, it was immediately applied to several applications, such as medical and materials processing – but technology was not mature enough at that time, so a phase of great enthusiasm was followed by a phase of even greater disappointment of the user society which lead to further delays. Only now, 50 years later, the industrial and scientific communities created networks allowing coherent strategic approaches towards the exploitation of the huge application potential of “Tailored Light”. Especially in the 1980s, when industry started to implement Lasers in cutting and welding processes in large scale production first in electronics and later in automotive, the relevance of Lasers as key enablers for relevant innovations got obvious. Today, this relevance can be seen in stable growth of the market for optical technologies as a whole. It is expected, that with the capability of high power, high modularity and long life, in the next decade the technology will experience a serious boost and thus will lead to leveraged innovations in practically all relevant societal trends, such as mobility, health, energy or environment. The scope of these innovations is vast and in the following only a few highlights can be described briefly. For further in depth information please see www.ILT.fraunhofer.de. Direct Production of Next Generation Products Parts, components and products in general underlie geometry as well as material specific restrictions if conventional manufacturing processes such as casting, forging, milling, grinding etc. are considered, only. A part which has been designed for function exclusively might be not manufacturable with conventional processes and a part which is manufacturable shows functional restrictions due to not meeting the optimum design specifications. An alternative to dissolve this classical manufacturing dilemma is contributed by Laser based direct production processes such as Selective Laser Melting – SLM – and In-volume Selective Laser-induced Etching – ISLE. These direct production processes offer specific advantages such as nearly unrestricted geometrical freedom and unique achievable properties of the parts produced. Due to the newest availability of high-power, high-brightness Laser radiation another two dilemmas can be dissolved: 1. Scale vs. Scope and 2. Accuracy vs. Productivity. Hence, individual, integrated, next generation parts designed for function can be produced directly and very cost-effective. High Volume Selective Laser Melting (SLM) The ILT-developed SLM is a Laser Additive Manufacturing – LAM – process that produces (or “prints”) metallic components – layer by layer – directly from 3D-CAD data. Hence, the near-net-shape parts can be directly used in various applications, e.g. in the medical, aerospace (Figure 1) or automotive industry. Figure 1: Nozzle Guide Vane (NGV) patch for use in an aero engine additively manufactured by SLM However, the state-of-the-art process and cost efficiency is not yet suited for large scale series production. The major cost driver for SLM is the manufacturing cycle-time, which only depends on the volume of material that has to be builtup. Therefore, a significant increase of the build-up rate needs to be accomplished to achieve a larger process and cost efficiency. This increase of the build-up rate is accomplished by the use of increased Laser power. Concerning simple test geometries, the build-up time can be reduced to less than 10 % compared with the state-of-the-art. Hence, the individualized and cost efficient series production of complex shaped parts by High Power SLM becomes an economical reality. PRODUCTION AND MECHANICAL ENGINEERING 23 Figure 2: Laser polished injection glass mold half (left) and manufactured end product flacon (right) Figure 3: µ-tube made from fused silica manufactured by ISLE As a potential surface finishing operation Laser polishing can be used to accomplish certain minimized roughnesses and gloss levels automatically (Figure 2). In-volume Selective Laser-induced Etching (ISLE) The miniaturization of products in micro optics, medical technology and micro system technology requires transparent components with structure sizes in the μm-range and accuracies of sub-μm. In-volume Selective Laser-induced Etching (ISLE) is an appropriate manufacturing process for micro processing of transparent materials such as sapphire and glasses, e.g. fused silica. By focusing the subps laser radiation into the volume the material is locally modified. By scanning the laser focus with a certain pulse overlap, connected volumes of modified material are created in a first process step. The modified volumes are subsequently removed by chemical etching in a second process step. Exemplary, μ-tubes (Figure 3) made from fused silica can be produced by ISLE with an irradiation time of approx. 60 seconds. With high-rate laser ablation using ultra short pulsed laser radiation in the picosecond (ps) and femtosecond (fs) regimes, accuracies of less than 5 μm and surface roughnesses less that 0.5 μm can be achieved for e.g. the manufacturing of molds. Compared with conventional nanosecond (ns) ablation the accuracies have been signifi- Figure 4: Injection mold manufactured with 100 ns pulse duration (left, remaining resolidified melt / debris) and 10 ps pulse duration (right, complete avoidance of resolidified melt / debris) cantly increased (Figure 4). This test geometry has been manufactured with ns-ablation (left, remaining melt and debris) in comparison with ps-ablation (right, no remaining melt and debris) and adapted processing conditions with pulse burst ablation. In the meantime sub-ps-lasers with average powers of up to 1 kW are available and promise ablation rates in the order of cm3/s depending on the material. Laser milling becomes reality. Photonics Production Aachen Research in Photonics is focused to several regions in Germany. Due to the fact, that RWTH Aachen University is a leading German university in production research, photonics research in Aachen is focused to production. More than 800 full time researchers are working in fields of application such as utilisation of tailored light as a manufacturing tool, high power lasers and the development of production technologies for light sources like LED and OLED or optical components. Prof. Dr. rer. nat. Reinhart Poprawe M. A. Director, Fraunhofer Institute for Laser Technology ILT Steinbachstr. 15 D – 52074 Aachen Phone +49(0)241 - 8906 - 109 Fax +49(0)241 - 8906 - 121 Mail poprawe@ilt.fraunhofer.de Web www.ilt.fraunhofer.de NEW DIMENSIONS AND CURRENT SOLUTIONS IN PHOTONICS 24 Tools of Light Jenoptik produces laser systems that are indispensable to the photovoltaic industry and all its efficiency needs. A shimmering curtain moves across a wafer from one end to the other. It’s all over in a second, and the machine is ready to start again. What we cannot see with our bare eyes, however, is that in that short period of time, the device is able to create up to 20,000 microscopic holes in the silicon, each one between 50 to 100 μm in diameter. And this takes just a single laser source that is scanned across the wafer by a special mirror system. This innovation is part of the Jenoptik Group’s most recent initiative for the solar industry. Even as recently as 2009, experts had yet to foresee the massive decline in solar cell prices – and increase in demand – we are Metal Wrap Through (after etching) Jenoptik’s laser applications lab of JENOPTIK Laser GmbH and who works closely with researchers at the Fraunhofer Institute for Solar Energy Systems in Freiburg, Germany. One idea involves removing contacts from the front side of the solar cells for more surface to convert sunlight. Solar cell efficiency thus increases by 0.4 to 0.6 percent – which may not sound like much, but since solar cells are only 17 percent efficient as a rule, every increase is welcome. In the new designs, contact “fingers” are incorporated into the backs of the cells. This can be done in one of two ways: Either metal contacts connect the front and back and carry the electrical charge through (“metal wrap through”), Laser Doping for Selective Emitter (surface texture after laser doping), source: Fraunhofer ISE Laser Ablation of Dielectric Layers witnessing now. The photovoltaic industry has thus entered a new phase in which more efficient production methods and higher cell efficiency are both crucial in terms of competition. Lasers play a very important role in this, especially when it comes to the crystalline silicon solar cells that make up more than two thirds of the market. Unlike thin film solar cells that have been produced with Jenoptik lasers from the start, the more traditional crystalline silicon cells have so far been produced using semiconductor processes. “But as completely new cell concepts are now needed, production methods also have to change. And lasers are the method of choice”, said Guido Bonati, president of JENOPTIK Laser GmbH, located in Jena, Germany. “People have thought of all sorts of clever ways to obtain more efficiency,” said Klaus Stolberg, who is in charge of or the semiconductor is itself shaped differently so that the emitter points through to the back (“emitter wrap through”). Either way, holes are required to “wrap” them to the back – and these holes are formed through the use of lasers. “Lasers are non-contact, highly precise, and fast. Other procedures would either be far too slow or environmentally unsound. Also, lasers do not damage the material, and microcracks are avoided”, explained Klaus Stolberg. The challenge his team faced was to cater to the varying wafer properties within the industry. The solution does not only solve the problem, but also presents a unique selling point: As the first company on the market, Jenoptik offers a tunable laser. Both its pulse repetition rate and pulse lengths can be adjusted for differences in wafer thickness, and it drills microvias faster than anything else available. The JenLas®disk IR70 laser was presented for the first time at PRODUCTION AND MECHANICAL ENGINEERING 25 Klaus Stolberg, Manager Laser Applications JENOPTIK l Lasers & Material Processing Lasers Business Unit the 25th European Photovoltaic Solar Energy conference and exhibition in Valencia, Spain, in September 2010. But that’s not all. The JENOPTIK-VOTAN™ Solas 1800/3600 serves the solar industry with a ready-to-use production system that uses every available method to make both solar cells and the production process more efficient. The modular system is able to process more than 3,600 wafers an hour in its fully automated version, all while allowing for a choice of features. One of the features that JENOPTIK-VOTAN™ Solas performs is selective emitter doping as a means of making solar cells up to another 0.6 percent more efficient. Laser Fired Contacts, source: Fraunhofer ISE Andreas Büchel, Product Manager "Crystalline Photovoltaics", JENOPTIK l Lasers & Material Processing Laser Processing Systems Business Unit Laser fired contacts, yet another feature, use lasers to literally shoot metal contacts through the electrically isolating passivation layer. This leads up to 20,000 high-quality contacts in solar cells. As a fifth feature, the machine provides for laser edge isolation, which isolates the negative and positive terminals of the cells from each other in order to avoid short circuits between front and back. A laser is used to scribe a precise groove all around the edge to remove the emitter. One last feature is Jenoptik’s thermal laser separation method, which is used to cut wafers. A laser beam applies its energy along a line, both warming and expanding the Thermal Laser Separation Laser Edge Isolation The silicon, which is conductive for positive charges, needs to be prepared (doped) for negative charge carriers. Previously, the entire wafer had been doped. “With the new method, laser light is used to insert the doping material only into selected contact regions. This is very efficient, as several tens of contact fingers can be doped simultaneously”, said Andreas Büchel, product manager “Crystalline Photovoltaics”, JENOPTIK Automatisierungstechnik GmbH. The machine’s laser ablation feature is used to drive a metallization paste through the top layer of the photovoltaic wafer to form an electrical contact with the emitter. This means that the dark blue top layer of silicon nitride needs to be opened locally – and with caution, as the nanometerthin emitter lies beneath it. Jenoptik provides the precision needed with a femtosecond laser. material. A cooling agent is then immediately applied to reabsorb the energy. The material then cools down and – as if by magic – breaks with microscopic precision, without material contact or loss. The innovation received the Best of West Award 2008, and was predicted to have a major impact on semiconductor production. And it has also become an essential Jenoptik product for the photovoltaic industry as part of the JENOPTIK-VOTAN™ Solas system. JENOPTIK I Lasers & Material Processing JENOPTIK Laser GmbH Göschwitzer Strasse 29 D – 07745 Jena Phone +49(0) 3641 - 65 - 4300 Mail info.lm@jenoptik.com Web www.jenoptik.com/lm NEW DIMENSIONS AND CURRENT SOLUTIONS IN PHOTONICS 26 Challenges in Modern Optics Andreas Tünnermann, Fraunhofer Institute for Applied Optics and Precision Engineering IOF, Jena which are essentially influenced by physical effects and not by chemical imperfections. “New” materials are currently being qualified for high-performance optics applications in the optics industry. In addition to semiconductors and ceramics, carbon-based materials such as diamond are being increasingly used. This latter features, excellent optical, mechanical and chemical properties, including a wide transparency range at a simultaneously high damage threshold and both heat conductivity and chemical inertness, of key importance for high-performance applications. Similar benefits are offered by sapphire and silicon, which can be produced with a high degree of purity and are of considerable interest for future optics applications. The micro- and nanostructuring of optical materials today means that it is possible to realize fundamentally new – artificial – material properties independent of intrinsic material parameters. Analogous to the behavior of electrons in crystal lattices, it was determined that light behaves similarly in expanded Spectral characterization of light transmission by optical metamaterials dielectric structures with periodically varying relative refractive indexes – so-called photonic crystals – if the period interval only has a magnitude of half the wavelength. In periodic media such as this, light has new, specific propagation properties which are unknown in conventional media. The appeal of these new media lies in the fact that the properties can be set via the geometry (period interval, symmetry, relative refractive index) of the photonic crystals. Today, threedimensional structures can be produced to prevent the propagation of light in all directions in specific frequency ranges. If The control of light in all its properties will play a key role in the defining technologies of this century. This covers its guiding and both spatial and temporal shaping, even under the most extreme conditions with regard to wavelength, power, and time. For this purpose, optical functional units will be integrated within one system with general or complete functionality. Thanks to the work of materials scientists and chemists in recent decades, the optics industry now has a large number of organic and inorganic materials at its disposal with controllable optical properties. A prominent example from the field of glass concerns fused silica (SiO2), the base material for a multitude of optical elements such as the optical fiber which has enabled the non-diffractive diffusion of light in the near infrared spectral range over tens of thousands of kilometers and thus revolutionized transmission of information. Ultramodern transmission fibers show intrinsic attenuation losses of less than 0.1 dB/km, Spliced fiber bundle PRODUCTION AND MECHANICAL ENGINEERING 27 Laser spliced fiber defects are entered into these structures, the light can be localized to these defects on tiny areas or be guided along specific paths. The combination of dielectric and metallic nanostructures enables the realization of metamaterials, whose material constants permittivity εr and permeability μr can assume negative values. Of particular interest are metamaterials with real relative reflective indexes in the range -∞ < n <1. These materials promise perfect imaging beyond the Abbe limit. The manufacture of these artificial optical materials is extremely complicated and requires recourse to processes in laser and electron beam lithography. The linking of these “new” materials with traditional refractive and diffractive optics to produce complex optical Diffractive optical element, etched into fused silica glass Loop of 9 coupled micro disc resonators. Parameters of a micro disc: diameter: 40 µm, thickness: 1 µm, distance between the resonators: 400 nm SEM micrograph of the cross section of a photonic crystal fiber Micro-optical pyramid structure for light outcoupling, prepared by electron beam lithography Andreas Tünnermann in the laboratory functions presents a particular challenge today, as microand nanostructures must here be functionally integrated in macroscopic systems. Optical systems engineering represents the technological platform for the manufacture and hybrid integration of such optical systems. Among others, it presupposes the introduction in optics of production processes adapted from the semiconductor industry such as highly parallelized wafer level-based production technologies or bonding technologies. Optical technologies are thus at a similar technological crossroads as electronics were in the 1960s, when the step from discrete components to microchips was taken. Such components will in future constitute miniaturized versions of well-known optical elements and enable the implementation of totally new optical functions, opening up the development of new areas of application for optics in important emerging areas: energy, information, environment, health, mobility, and safety. Fraunhofer-Institut für Angewandte Optik und Feinmechanik IOF Albert-Einstein-Str. 7 D – 07745 Jena Phone +49(0) 36 41 - 807 - 0 Fax +49(0) 36 41 - 807 - 600 Mail andreas.tuennermann@iof.fraunhofer.de Web www.iof.fraunhofer.de NEW DIMENSIONS AND CURRENT SOLUTIONS IN PHOTONICS 28 Optical Imaging in Life Sciences and Medical Diagnostics Markus Sticker The developed countries are facing a rapid demographic change towards an ageing society. This will confront the health care systems with enormous challenges. The case number of cases of age-related diseases like cancer, dementia, cardiovascular diseases, and loss of sight is expected to rise sharply over the next decades. At the same time, the financial resources of public health care systems are likely to decline and therefore not keep pace with the expected increase in costs for treatment and nursing care. To address these challenges, medical research and practice must advance towards better prevention of diseases, their early and specific diagnosis, and towards personalised therapies. Optical imaging techniques hold the potential to successfully address these challenges in various fields from research to diagnostics. Some of the most impressive developments in recent years are presented here. Optical Imaging in Life Science Research PhotoActivated Localization-Microscopy (PAL-M) is a technology at the leading edge of research and innovation. The more than 10 fold increase in lateral resolution offered by PAL-M represents a significant breakthrough in fluorescence microscopy. PAL-M utilizes the principle of pointillism to resolve structures far below the diffraction limit. The principle benefits from the fact that a system can spatially resolve two very close molecules, provided that they are imaged sequentially. Recent advances in labeling techniques enable this relatively easily. A highly modified form of a total internal reflection fluorescence microscope (TIRF) is used in order to achieve the out-of-focus discrimination and speed needed for single molecule detection. Thousands of images are rapidly acquired, and then used to compute a superresolution image. Given this unprecedented resolution, cellular organization and communication and dynamic processes which for example endow our brain with its impressive processing capability can now be explored in extraordinary detail. PAL-Microscopy allows the scientist to peer inside living cells to study dynamic interactions down to the size of individual molecules. Often researchers need to explore three-dimensional structures deep inside live biological samples. Here, multiphoton microscopy is the best choice. A single beam of a pulsed, ultrafast and tunable infrared laser is rapidly scanned across the sample. A high level of laser output power is required to achieve the necessary photon density at the focus, such that it becomes highly probable that two or more photons will excite a fluorophore in a similar way to single photon with half the wavelength. However, outside the laser focus the light intensity decreases exponentially, and the laser light rapidly becomes too weak to generate fluorescence emission. This well-confined focal excitation provides some crucial advantages: The emitted light can be collected much more efficiently, and the infrared radiation used penetrates much deeper into biological tissue. Optical Imaging for Clinical Diagnostics Histopathology: Since more than 100 years the microscope is the fundamental instrument in the daily work of pathologists in their diagnostic work with tissue and cells. Research of cell migration. CLC2 cell expressing tdEOS-Paxillin. Left: high resolution PAL-M image. Right: Sum widefield image with diffraction-limited resolution. Sample kindly provided by Mike Davidson, University of Florida. LIFE SCIENCE 29 Cross-sectional OCT image of the papilla in micrometer resolution. Analysis of the retinal nerve fiber layer thickness. Multicolor Multiphoton Imaging: Projecting neurons in Drosophila melanogaster, antibody triple staining showing synaptic connectivity. Virtual microscopy and today’s IT infrastructure are currently changing the classical workflow into a digital one. Microscopic images of whole tissue sections can now be saved as a virtual slide. The virtual slide is stored on an image server where the image data can be accessed via intranet or by internet from all over the world at any time. Specific features within the images can be quantified with image analysis software, offering the pathologist additional information for a more detailed diagnosis. Ophthalmology: With over 9.000 systems installed worldwide, optical coherence tomography (OCT) has entered the field of ophthalmology with great success. Light backscattered from retinal structures is analysed interfer- Intraoperative images demonstrating a tumor cavity viewed under conventional white light (left) and violetblue illumination with the appropriate observation filters (right). The patient had previously been given 5-ALA. Images kindly provided by Walter Stummer, University Hospital Münster. ometrically. The short temporal coherence of broadband light sources allows depth resolutions in the micrometer range. Rapidly scanning the beam over the retina enables to acquire 2D or 3D data sets. Cross-sectional images and maps reveal the details of retinal abnormalities that are otherwise difficult to detect. Important applications include the diagnosis of age related macular degeneration (AMD), the most prevalent cause of sight of loss in elderly people, and follow up evaluation of therapeutic response. Damage related to Glaucoma can also be tracked by evaluating the retinal nerve fiber layer and optic nerve head. Surgical microscopes are used as optical and digital visualisation systems in various fields like neuro-, ophthalmic- and ENT- (ear, nose and throat) surgery. It is particularly important in neurosurgery to develop reliable, minimally invasive and efficient surgical procedures. When removing malignant brain tumours, the main difficulty is distinguishing between healthy tissue and the edges of the tumour. Pre-operatively administering 5-ALA to the patient, the malignant tissue shows up red using fluorescence-assisted surgical technology. This enables the surgeon to work with much more precision and to remove the tumour completely, without compromising the vital functions of the brain. Carl Zeiss MicroImaging GmbH Dr. Markus Sticker Advanced Development Microscopy Carl-Zeiss-Promenade 10 D – 07745 Jena Phone +49(0) 3641 - 64 - 2914 Mail M.Sticker@zeiss.de Web www.zeiss.de/micro NEW DIMENSIONS AND CURRENT SOLUTIONS IN PHOTONICS 30 Endoscopic Imaging and Treatment Dr. Klaus-Martin Irion Global Vice President Research & Technology KARL STORZ GmbH & Co. KG New endoscopic solutions continue to expand the spectrum of medical examinations and interventions now and in the future. Over the last 20 years, endoscopy has gained considerable importance in the field of medicine. This is down to new optoelectronic visualization technologies and the transition from open to so-called minimally invasive surgery (MIS). This technique allows complex, surgical interventions through the smallest, artificial openings using remote controlled surgical instruments and thin caliber endoscopes. Today, MIS interventions are performed with rigid endoscopes, while flexible endoscopes are primarily employed in diagnostic applications via natural orifices. The decisive advantage of this operating technique is the considerable reduction in the trauma caused when creating an approach as there is no need for extensive abdominal incisions. Consequently, patients suffer considerably less pain, experience shorter recovery times and can return to work more quickly. Rigid endoscopes have already existed for over 100 years. The technological breakthrough in terms of image quality and risk minimalization came in the 1960s when Karl Storz introduced cold light and the transmission of the light via integrated optical fibers [1] and with the transition from conventional lens systems to so-called rod lens systems led by Harold Hopkins [2]. The first flexible endoscopes based on arranged image waveguide bundles were introduced by Hirschowitz [3] in 1957. Fig.1: Rigid HOPKINS® rod lens endoscope with high resolution 3-chip camera system (left), endoscopic HDTV image in 16:9 format (right). Fig. 1a Fig. 1b Nowadays we differentiate between three endoscopic visualization systems: 1. Rigid HOPKINS®rod lens endoscopes with proximal HD camera system (Fig.1) This system combination of high resolution optical transmission system and the best electronic and endoscopically employable imaging system with 3-chip technology currently available guarantees an image quality in HDTV quality in the 1080p standard along the whole length of the transmission path. 2. Flexible videoscopes with a distally integrated miniature image sensor (Fig. 2) The videoscopes with distal image sensor technology have now almost completely replaced conventional, flexible fiber endoscopes with larger endoscope diameters. In comparison with fiber endoscopes, videoscopes offer improved image resolution by about tenfold. Localized image errors resulting from broken fibers do not occur with electronic endoscopes. 3. Semi-flexible mini-endoscopes with proximal camera (Fig. 3) Extremely thin caliber endoscopes with diameters of up to 0.3 mm can be realized via semi-flexible multifiber bundles. Their resolution can reach up to 50,000 pixels depending on the diameter. The main application fields of these miniature endoscopes are the diagnosis and treatment of very small lumen hollow organs such as the tear duct or salivary duct. In addition, these types of systems have recently been utilized for optical biopsies. Fig. 2: Flexible video bronchoscope system with integrated camera control unit including light source, monitor, keyboard. Fig. 2 LIFE SCIENCE 31 Fig. 4: Multi-functional flexible platform for performing endoluminal operations: ANUBIS® NOTES scope with three working channels, of which two can be angled; whole system (left), distal end piece with coagulation forceps and suction catheter (right). Endoscopy and MIS surgery are a success story for how an imaging system can be optimally combined with a treatment approach. The new NOTES technique (Natural Orifice Transluminal Endoscopic Surgery) represents a possible further development for MIS and flexible endoscopy. This is an operative, endoscopic procedure in which the instruments are introduced through natural orifices, such as the mouth, vagina, or anus, using a flexible endoscope. A small intra-corporeal incision in the stomach, the vagina, or the intestine allows the surgeon access to the actual operating site. Following the successful completion of the operation the incision is sealed with the corresponding closing technique (clip, staples). The advantage of these methods is that the approaches usually heal without pain for the most part and that they involve no external scars. This technique is essentially still experimental but is already being used on patients in a number of variations [4]. The longer, indirect approaches place new requirements on the endoscopic operating systems, which could not be adequately fulfilled by the previous, flexible endoscopes. For this reason, flexible endoscopic operating platforms have been developed, which make operations using two flexible instruments possible. (Fig. 4) The function of the folding out of the instrument working channels allows ergonomic handling of the instruments in a defined triangulation angle in front of the optical system. As a result of the longer, flexible channels, the coupling of energy, e.g., for tissue cutting and coagulation, Fig..4a Fig. 4b is still proving difficult in NOTES. Alongside existing high frequency surgery methods this is a good possibility for lasers with flexible applicator systems to establish a place for themselves. It is still not possible to foresee to what extent and in which medical applications NOTES will be successful. However, it is now clear that new technological challenges are to be expected in terms of optoelectronic imaging, miniaturization and the system integration of microoptics, microelectronics and micromechanics. Literature [1] DE 1113788 (1962) Einrichtung an Endoskopen mit einer proximalen Lichtquelle (Equipment on endoscopes with a proximal light source) [2] US 3,257,902 (1966) Optical System Having Cylindrical Rod-Lenses [3] Berci G. (1976) Endoscopy Application, Century-Crofts [4] Marescaux J. (2007) Surgery without Scars, Arch Surg 142 (9): 823-827 Dr. Klaus M. Irion KARL STORZ GmbH & Co.KG Mittelstrasse 8 D – 78532 Tuttlingen Phone +49(0) 7461 - 708 - 219 Mail k.irion@karlstorz.de web karlstorz.com Fig. 3: Mini-endoscope system for diagnostics and treatment of calculi in the salivary duct. Outer diameter: 1.1 mm; Working channel: 0.45 mm; Irrigation channel: 0.2 mm. Fig..3a Fig. 3b Fig. 3c NEW DIMENSIONS AND CURRENT SOLUTIONS IN PHOTONICS 32 Analytical Applications in Life Sciences and Diagnostics Dr. Peter Schubert, Director R&D, R-Biopharm AG Introduction A wealth of applications in life sciences and diagnostics utilize optical measurements to determine the concentration or activity of for example biomarkers or contaminants. The applied measurements are based on optical principles as diverse as absorption, fluorescence, luminescence, refractometrie or surface plasmon resonance. Analytical methods in life sciences are integrated approaches that have to combine some or all of the following steps: sample preparation, analyte separation, specific labelling, sensitive detection and data analysis. These often complex procedures require in many cases a considerable amount of time, the infrastructure of a laboratory and trained staff. A challenge of today is to convert these laborious procedures into easy to use test formats that can be applied at the point of need by untrained people. To do so, robust assays and portable, miniaturized instrumentation have to be developed. In the following, concepts of analytical procedures in the life sciences with considerable impact in the field are introduced. However, a detailed review is beyond the scope of this article. Figure 1: Schematic multiplex lateral flow test strip: A defined volume of a solution containing the biomarkers or contaminants of interest is applied to the sample pad. While the reagent pad is soaked with the sample solution, the binding of specific detection reagents to the analytes takes place. The solution is running over the membrane driven by capillary force. When the reagent/sample solution is passing through the test lines, the analyte/detection reagent complexes are captured by immobilized analyte specific antibodies at the respective testline, while excess unbound detection reagents pass the lines. The control line is necessary to capture the excess of detection reagents. If detection reagents are captured at the control line, the test run is valid. The waste pad absorbs the excess sample solution. The test strips are mounted into a plastic housing for better handling by the customer. Analytical applications A very successful application of the above mentioned principles is the polymerase chain reaction (PCR). A great deal of applications and instruments have been developed that allow the detection of theoretically a single molecule of DNA. During the PCR-reaction, the amplification of a specific DNA-fragment is accompanied by the amplification of a fluorescent signal that can be detected in real time (real time PCR). The unparalleled sensitivity has lead to a widespread use of real time PCR in fields as diverse as food and feed analysis (e.g. detection of genetically modified organisms), clinical diagnostics (e.g. pathogen detection, gene analysis) or cancer research (e.g. expression patterns of tumour markers). PCR is, however, a laborious method that requires trained staff and complex instrumentation. Since the enzymatic DNA amplification requires cyclic heating and cooling, the instruments have a large energy consumption. Furthermore intense sample preparation is necessary which may lead to contamination and false results. With the available assays and instrumentation it is therefore not possible to apply this method directly at the point where the information is LIFE SCIENCE 33 needed, for example at the bedside in the clinic. Recent developments in the field of isothermal PCR may lead to nucleic acid amplification and detection at the point of care in the future. The basic biochemical concepts for amplification already exist, furthermore easy to use portable instrumentation is available that offers thermal control of the enzymatic reactions and sensitive fluorescent detection with data analysis. If it is possible to simplify the sample preparation for isothermal PCR, this technique will be a promising application in the future. Point of care test systems (clinical diagnosis) or field tests (food and feed analysis) gain considerable attention. They allow for example a fast diagnosis of critically ill people or a quick decision whether a product is contaminated or not at the point of need. Such test systems must offer a titative readout of test strips by fluorimetry or reflectometry and the calculation of analyte concentrations (Figure 2). The introduced techniques, PCR and lateral flow assays are very different, but they share the need to use a label (fluorophore or coloured nano particle) and a specific biomolecule for analyte detection. Analyte specific biomolecules like antibodies and nucleic acids can be modified with labels for sensitive detection. Furthermore antibodies and nucleic acids bind with very high specificity and affinity to their respective target of interest and can therefore be used to trigger specificity in analytical applications. In the future, these specific biomolecules (especially antibodies) and the respective reporters (e.g. enzymes or fluorophores) should be generated exactly suitable to the requirements of the application that is to be developed. Figure 2: The RIDA® QUICK SCAN electronic test strip reader was developed to meet today's increasing quantification and documentation requirements. The reader can be used as a portable battery-operated mobile or as a stationary unit in a laboratory. After incubation, the test strips are placed in the reader and read by an optical unit. Use of the reader ensures an objective evaluation of test bands present on the test strips. These might be either printed on a portable printer using thermo paper, or may be exported via USB to a PC. short time to result and they should be very easy to apply. Furthermore the sensitivity and specificity of the analyte detection must be comparable to lab based methods. One approach that offers fast and reliable data generation and ease of use is the so called immunchromatographic test or lateral flow assay. Membranes, antibodies and detection reagents are combined in a way that complex samples can be analysed with a test strip and the result is obtained within 15 minutes (Figure 1). Crude samples can be used, without the need for excessive and time consuming sample preparation. The key technology of lateral flow assays are analyte specific antibodies coupled to coloured nano particles (e.g. colloidal gold or latex beads). The more analyte is present in a sample, the more of the labeled antibodies are immobilized at a defined location and can be detected with an optical readout. It is, however, necessary to lower the detection limits of these assays or to develop new detection principles. For many years lateral flow test strips allowed only a qualitative or semi-quantitative result, but latest instrumentation offers today the possibility for quan- Conclusion The key principles of many successful analytical applications in life sciences and diagnostics are the combination of analyte specific biomolecules with a sensitive optical detection. Robust, easy to perform assays and miniaturized instrumentation for the use at the point of need are already available. It is, however, necessary to develop applications for the use with crude samples and to lower the detection limits of currently available assays. Dr. Peter Schubert R-Biopharm AG An der neuen Bergstraße 17 D – 64297 Darmstadt Phone +49(0) 6151 - 8102 - 37 Mail p.schubert@r-biopharm.de Web www.r-biopharm.de NEW DIMENSIONS AND CURRENT SOLUTIONS IN PHOTONICS 34 Fast Communication with Light – Photonics for the Networked Society Jörg-Peter Elbers ADVA AG Optical Networking Photonic communication networks form the foundation of our networked society. Whether it is a voice call, an email, or a multimedia application, or whether we use a smart phone, computer or TV: optical networks always provide for a fast, secure and reliable transport of the required data, all the while remaining invisible to the user. And optical networks are essential for machine-to-machine communication also: Be it connections between data center servers, or system components in a car, plane or ship – without photonics, many areas of daily life would remain in the dark. Product innovations made in Germany a) 40/100 Gb/s capable optical transport platform from ADVA AG Optical Networking (top left) b) 100 Gb/s protocol tester from JDSU (top right) c) coherent 40 Gb/s long-haul transceiver from Cisco-CoreOptics (bottom left) d) coherent 100 Gb/s receiver module from u²t (bottom right) The importance of photonic networks will increase further in the future: Continuous traffic growth [1] can only be sustainably managed with fiber-to-the home/office roll-outs. Due to its practically unlimited bandwidth, fiber connections are fast-becoming an important factor for locating businesses, and drive the development of new services and applications. The trend to source storage, applications and computing resources in data center “clouds” poses new challenges for high-speed optical networks (including flexibility, scalability and energy efficiency). Photonic technologies will also increase their influence within the data center, moving from parallel optical interconnects over chipto-chip to on-chip photonics. In addition, new applications will demand more photonic networking technology: Be it information networks for smart grids/smart metering/smart cities or networks for e-health/e-learning/e-government – photonic networks will provide the robust infrastructure required for the delivery of mission-critical applications. With a global volume of approximately 20 Billion USD [2], the photonic communications market is a strategic one for the future. Boasting a network of more than 50 companies and 20 universities/research institutes, Germany is one of the world’s leading research and development centers for optical communications technology. Germany is the third largest exporter of telecommunications technology in the OECD after Korea and the USA [3]. Optical communications technology from Germany is renowned on an international level. Companies such as ADVA Optical Networking, AlcatelLucent and Nokia Siemens Networks, as well as a number of smaller enterprises (e.g., Keymile, ELCON, Microsens) deliver systems, subsystems (e.g., FOC, Cisco-CoreOptics) Researchers from Fraunhofer Heinrich Hertz Institute carrying out high speed optical transmission experiments COMMUNICATION AND INFORMATION 35 Strategic research areas in photonic communications and components (e.g., u2t). Several of these companies also undertake production in Germany (e.g., ADVA Optical Networking, ELCON, Microsens, Nokia Siemens Networks, u2t). In addition, measurement equipment (JDSU), cabling systems/vehicle networks (e.g., LEONI, ADC Krone) and components for optical interconnects (e.g., Vertilas, ULM Photonics) are developed in Germany. Photonic communications solutions are a good example for high-tech „Made in Germany“. Recent product innovations developed in Germany include: 40 Gb/s and 100 Gb/s transponders/muxponders for wavelength division multiplex systems (ADVA Optical Networking, Alcatel-Lucent, Nokia Siemens Networks), 40 Gb/s transceiver modules (Cisco-CoreOptics), coherent 100 Gb/s receivers (u2t) and 100 Gb/s protocol testers (JDSU). These successes were partly facilitated by research grants from the BMBF (German Ministry for Education and Research), more specifically in the research programs Eibone and 100GET. A new BMBF research program „Nextgeneration broadband access networks“ has just started and targets the development of novel fiber to the home (FTTH)"solutions. In addition, three strategic research areas for photonic communications were identified in the framework of the „Photonik 2020“ initiative: „Photonics for the information highway“, „Photonics in data centers“ as well as „Photonics everywhere“. In all, these areas are attractive opportunities for focused R&D to drive the networked society „at the speed of light“. [1] The global IP traffic alone grows 34% per year. Source: Cisco Visual Networking Index 2010. [2] Source: Photonics21 Strategic Research Agenda 2009 and own research. [3] Source: OECD Communications Outlook 2009. Dr. Jörg-Peter Elbers Vice President Advanced Technology CTO Office ADVA AG Optical Networking Fraunhoferstr. 9a D – 82152 Martinsried Phone +49(0) 89 - 890665 - 617 Fax +49(0) 89 - 890665 - 22617 Mail JElbers@ADVAoptical.com Web www.ADVAoptical.com Anzeige UItrafast Pulse Diagnostics Autocorrelators|Spiders your partner in ultrafast Wavelength Conversion OPOs|Harmonics Generators Pulse Management APE Angewandte Physik & Elektronik GmbH Plauener Str. 163 - 165 Haus N|13053 Berlin|Germany Phone +49 30 986 011 30 ape@ape-berlin.de|www.ape-berlin.com Pulse Compressors|Cavity Dumpers|Pulse Pickers Acoustooptics AOM|DFD NEW DIMENSIONS AND CURRENT SOLUTIONS IN PHOTONICS 36 Convergence? – Microphotonics as the Successor Technology to Microelectronics? From Internet backbones and satellite links to connecting buildings and apartments, the future of wide area networks belongs to photonic transmission technology. Mobile telephony – and certainly broadband mobile telephony – would be unthinkable without fiber optic infrastructures. In computer technology too, whether it be board-to-board or chip-to-chip connections, photonic transmission is steadily increasing in importance. In this context, integrated microphotonics seem a development designed to overcome the limitations of microelectronics. When it comes to wide area transmission, everybody agrees that photonics are a key technology. The spread of high bit rate applications from the multimedia sector – pictures, videos and TV in fixed and mobile networks – and continually rising levels of data traffic are the two factors driving comprehensive use of fiber optics. Technologically speaking, this is obvious, but it’s now national programs and political decision-making that set the pace of coverage, both of wide area networks (WANs) and local connections as with Fiber-to-the-Home (FTTH). Mainly realized through the satellite infrastructure, global area networks will increasingly rely in the future on photonic satellite-to-satellite and terrestrial-to-satellite links. In tandem with this, mobile wireless base stations with the new LTE (Long Term Evolution) mobile wireless standard are being networked with fiber optic cables. In short, we can expect exponential growth in data rates and data volumes with ever more powerful end devices. Since the 1970s electronic integrated circuits have been a key building block for the progressive networking of society. Complex circuits, and particularly ever more powerful end devices, PCs and smart phones, were only made possible by the advent of microelectronics. Continuous advances in capability and performance – like higher pulse frequencies and larger numbers of integrated transistors – have leveled out over the past few years. Physical limits and limits in chip manufacturing have led to what has been termed “multi-core processing technology” as a viable alternative which can offer higher computational power per CPU, more efficient use of energy and so on. Such multi-core processing technology, however, places high Electro optical modulator demands on the data with travelling wave electrode for high Frequency application transmission rate not only between cores COMMUNICATION AND INFORMATION 37 Prof. Dr.-Ing. Hans-Joachim Grallert Executive Director of the Fraunhofer Heinrich Hertz Institute themselves but also on board-to-board and chip-to-chip connections. This means that apart from general issues of higher performance there is also a need for solutions for key problems such as heat removal from tightly packed chips or the complex connections between silicon modules. Such sets of requirements can only be addressed by photonic transmission technologies. Against this background, microphotonics is developing into a research field with high potential – and with also high expectations placed on it. Can microphotonics replace microelectronics in a similar way to how glass fiber optics replaced expensive, limited capacity, energy guzzling and less scalable copper wires? Can microphotonics turn into a killer technology – one that makes existing technology obsolete? Photonics itself has shown in transmission technology that it is indeed fully capable of replacing the established techniques with qualitative new ones. lent chances for taking a lead position on the emerging microphotonics market. This is the point where the experiences of institutions and enterprises in Germany can play their part. For instance: • Basic chip-level technologies • CMOS/SiGe based electronic components (IHP – Leibniz Institute for Innovative Microelectronics; realization in association with the Technical University of Berlin) • III/V-based optical and optoelectronic components (Fraunhofer HHI) • Hybrid wafer-level integration (Fraunhofer IOF – 3D Integration on the Wafer Level; Fraunhofer IZM – 3D chip stacking) • Polymer-based hybrid integration (Fraunhofer HHI – technology and fully fledged applications in association with FOC, u2t, Aifotec) • Board-level hybrid integration of optical interconnects based on thin glass with special emphasis on waveguide technology and interface concepts (Fraunhofer IZM in association with Siemens, Würth Electronics and ERNI Electronics) In a first phase, convergence between microelectronics and microphotonics is set to have tremendous importance – because especially in photonics there are still a lot of unanswered questions such as: • How is light generated in silicon-based technologies? • Which silicon-based technologies should be used for which purpose? • Can manufacturing costs be significantly lowered? • Can design and fabrication methods be largely standardized? • How and where can broad expertise in microphotonics be built? Much research work in the direction of microphotonics or (hybrid) photonic integration has already been initiated – and has already delivered some presentable promising results. Even so, microelectronics and microphotonics still seemed destined to live together for a long time yet in a state of convergence. Particularly in terms of expertise in microphotonics, Germany is excellently positioned with its universities, research facilities and small and medium-sized enterprises. The chief competitor in this global marketplace is the USA which invests heavily in the development of microphotonics. Yet cooperation with European partners – for instance within the framework of Photonik 2020 – still offers excel- Prof. Dr.-Ing. Hans-Joachim Grallert Executive Director Fraunhofer Heinrich Hertz Institute Einsteinufer 37 D – 10587 Berlin Phone +49(0) 30 - 31002 - 200 Mail hans-joachim.grallert@hhi.fraunhofer.de Web www.hhi.fraunhofer.de NEW DIMENSIONS AND CURRENT SOLUTIONS IN PHOTONICS 38 Image Acquisition and Projection Techniques: Modern Head-up Displays for the Automotive Industry Markus Ehbrecht QIOPTIQ Photonics GmbH & Co KG Recent progress in image acquisition and projection techniques has influenced the usage of technological equipment in various fields, such as Medical & Life Sciences, Security, Industrial Manufacturing and Entertainment. Image acquisition will be extended from the classical 2-D image to multimodal and multispectral imaging and combined with enhanced data processing to allow much higher degree of automation and real time analysis. Topics of current research activities cover several areas like illumination, system design and methods for data processing. Fusion of data from various sources will lead to a more comprehensive level of information and will enable more robust automated decisions in a shorter time, which is especially interesting for medical and security applications. Also, the field of image projection benefits from new developments and is boosting one of the current social megatrends: mobility. With the miniaturization process in electronics and the development of broadband data transfer solutions, advanced projection devices are the key to the availability of mobile visual information. It is expected that multi-media devices like laptops, mobile phones, or Fig. 1: Israel, et. al. 2010: Contact analog Information in the Head-up Display – How much information supports the driver?, in "Advances in Ergonomics Modeling and Usability Evaluation", CRC Press Inc., Picture courtesy of AUDI AG Frank Guse QIOPTIQ Photonics GmbH & Co KG cameras will be equipped with micro-projectors, based on integrated laser or LED-projection. Another class of systems are head-mounted displays (HMD) and head-up displays (HUD). Both are able to combine real world scenery with additional information (fig. 1) and are opening a new market for assistance systems. Currently HUDs are introduced into the automotive market. HUDs are optical projection devices that add visual information to the user’s field-of-view, so that the user sees the information with both eyes simultaneously and with the same eye accommodation as the user sees the outside world (fig. 2). As the standard usage of HUD is in far sight situations, the HUD's functionality is to generate a virtual image at a distance within the depth-of-focus of the unaccommodated eye, with an angular size and angular resolution that matches the human visual system. Further, the luminance of the virtual image needs to be adaptable to different daylight and night time conditions to ensure comfortable viewing while absolutely avoiding blinding. HUDs have been used in combat aircrafts for more than 40 years. In the late 1980's, American and Japanese car makers started to offer HUDs as an addition to the driver's instrument panel of high-end cars. Over the last decade, HUDs have also become available in European cars. Whereas most automotive HUDs use the windshield to reflect the information into the driver's field-of-view, French car maker Peugeot recently introduced a semi-transparent combiner mirror being located in between the windshield and the steering wheel. The projected information content changed over the years from the original speedometer and tachometer, to the addition of navigation systems, to the inclusion of warning symbols from a variety of driver assistance sensors such as distance radar, lane detection, and night vision cameras. Modern content management software displays information derived automatically from the current driving situation and is able to localize danger in the driver's field-of-view. As it is proven by studies that the driver's response time is reduced by a factor of 2x when a warn- COMMUNICATION AND INFORMATION 39 Fig. 2: Schematic of an automotive Head-up Display Fig. 3: One liter Head-up Display for mid-size and compact cars from QIOPTIQ ing symbol is directly projected into his field-of-view, HUDs are now acknowledged as an important safety feature in cars. The basic layout of a HUD typically comprises a transparent LCD that is backlit with LEDs, and a projection unit that generates the virtual image. The size of the virtual image, the projection distance and the eyebox format, i.e. the size of a window through which a cyclopic driver would see the entire virtual image, define the étendue of the projection system. As space constraints in cars prove to be the major obstacle for HUDs, it is the HUD's design challenge to find the most compact solution for a pre-defined étendue. The number of design variables, such as freeform optics and the position and orientation of the optical elements, easily exceed standard lens design tasks. A consistent data work flow from the lens design software to the diamond turning manufacturing of the molding tools needs to be assured, as well as assembly and test devices appropriate for freeform surfaces have to be provided. Although important groundwork was laid by the development of progressive-addition lenses in the spectacle industry, the technological maturation of freeform precision optics remains an active subject of current R&D programs. Today, typical automotive windshield type HUDs generate a virtual image of up to 200x80mm at a distance of 2m, that is visible in an eyebox window of 120x60mm2, and that fills a volume of 4 liters. Such HUDs may comprise up to five freeform mirrors made of molded plastics, building a complicated folded beam path. That type of system is too complex, too large, and too costly for most automobiles. As an innovative solution, we recently demonstrated a fullcolor HUD with the same étendue as the 4-liter system, that is only one liter in volume (fig. 3). This system was based on a combiner mirror, two reflective freeform mirrors, and two freeform lenses. To reduce weight and cost, these components were all molded from plastic materials. This new level of performance enables the integration of HUDs in mid-size and even compact cars in the future, thus opening a new exciting, up-to-now unaccessible market. Dr. Markus Ehbrecht Dr. Frank Guse Qioptiq Photonics GmbH & Co. KG Hans-Riedl-Straße 9 D – 85622 Feldkirchen (München) Phone +49(0)89 - 255 458 - 101 Fax +49(0)89 - 255 458 - 141 Mail frank.guse@qioptiq.de Web www.qioptiq.com NEW DIMENSIONS AND CURRENT SOLUTIONS IN PHOTONICS 40 Solid State Lighting – the Light of the Future Berit Wessler, OSRAM GmbH, München Introduction Light sources based on inorganic semiconductors, i.e. light emitting diodes (LEDs), are at the edge to start a new era in lighting: Solid State Lighting (SSL). What the transistor meant to the development of electronics, the lightemitting diode means to the field of photonics as these tiny light sources will revolutionize modern lighting due to their unique properties such as long lifetime, robustness, colour tuneability, and instantaneous switching. But most important: Light emitting diodes are mercury-free and will become the light source with the highest energy-efficiency in the near future. Thus, LEDs are able to outperform all existing light sources and can save significant amounts of energy as well as financial resources. Moreover, solid state light sources can go beyond pure replacement of existing light sources by providing new capabilities including the control of the spectrum, color temperature and spatial emission pattern. The perfect match to these point light sources are LEDs based on organic semiconductors (OLED) which enable a completely new type of light as they are extremely slim, diffuse area light sources. Status today LEDs made tremendous efficiency and brightness improvements within the last ten years thus enabling their entrance into many applications. There is no mobile phone today without these versatile light sources, starting from key pad illumination up to flash lights. Starting with dashboards in the interior of automobiles, LEDs have now also taken over the exterior lighting of cars: from break lights to even headlamps. In the short term, the LED market will be dominated by their for backlighting of laptops and LCD-TVs. The biggest boost to the LED market, however, is expected with the emergence of LEDs into the general lighting market, the “megamarket” of the future. OSRAM expects that the lighting market (without traditional luminaires) will double within the next five years with the growth coming exclusively from SSL. In 2015 65% of sales of the lighting market will be generated from SSL. The paradigm shift: Chances – Changes – Challenges If LEDs and also OLEDs are to reach high market penetration, significant progress is yet to be made in terms of performance and cost. Apart from technological challenges, a paradigm shift across the whole value chain will have to be managed as SSL is a completely different light source from today’s products which also has consequences for the luminaire market. Thus the lighting industry faces both, huge challenges on the one hand but also great chances for growth on the other hand. The chances: • Light with new functionalities will be available: adaptable, intelligent and individual • Light solutions will be demanded rather than single light sources • LED will open up new design possibilities and have an even greater social impact • Light will provide comfort, well-being and have positive influence on health The changes: • Long lifetime all the way up to mount & forget will impact business models: • Lamp replacement market will no longer exist • Lamp & fixture differentiation becomes somewhat blurry • Illumination transfers from consumer good to investment: Total cost of ownership rather than initial cost must dominate the buying decisions • “Abilities” become key: reli-ability, interchange-ability, upgrade-ability, maintain-ability • Guaranties gain more importance • New business models will come up: emergence of contracting LIGHTING AND ENERGY 41 LED chip fabrication at OSRAM Opto Semiconductors in Regensburg High brightness LEDs for illumination from OSRAM Opto Semiconductors Modern illumination with LEDs @ OSRAM Opto Semiconductors The challenges: To seize the above mentioned chances and also be prepared for the changes, the following fields of action need to be addressed. • Increase of system efficiency and decrease of system cost The two key challenges are performance and cost. The efficacy barrier of 100 lm/W for white LEDs has been broken in production but there is potential of up to 200 lm/W or higher. Thus the fierce efficacy race is ongoing. However, not only the LED itself but also the system components need substantial improvement, i.e. electronics, cooling and optics. Cost need to be reduced by a factor of ten by highly automated manufacturing and new process technologies. • Exploitation of the full potential of LEDs Intelligent lighting solutions need to be developed with controlled adaptation of intensity and spectral distribution. New functionalities need to be explored, i.e. combining lighting with communication in playable wallpaper or with photovoltaics for autarkic systems. In turn, team up between the lighting industry, light planners, architects and the building sector is crucial. • Exploration of the impact of light on health and wellbeing Non visual aspects of light on human beings, on their well-being, health and performance, is a fast growing and yet not well understood research field. One goal of the chronobiology is to strengthen the circadian rhythm by dynamic light. Scientific prove as well as more knowledge in the general public about light quality and these effects is needed. • Acceleration of turning technology into innovation One of the crucial factors to gain significant market share in this fast growing market is speed. For successful market penetration and to facilitate the shift to SSL supporting measures are necessary to accelerate the transfer from leading-edge technology into the market, i.e. demonstrate benefits of SSL in pilot projects, set-up incentive programs and elaborate new financing concepts. There are still many challenges ahead but the remarkable progress and prospects will pave the way for a bright future of solid state lighting. As innovation leader and one of the two leading lighting manufacturers in the world OSRAM is driving the transition to SSL. Historic city center of Regensburg illuminated by energysaving LED luminaires OSRAM GmbH Hellabrunner Str. 1 D – 81543 München Phone +49(0) 89 - 6213 - 3880 Email b.wessler@osram.com Web www.osram.com NEW DIMENSIONS AND CURRENT SOLUTIONS IN PHOTONICS 42 III-V Multi-Junction Solar Cells and Concentrating Optics A Perfect Match for Highest Efficiencies Dr. Andreas Bett, Fraunhofer Institute for Solar Energy Systems ISE, Freiburg 1. Introduction Photovoltaics (PV) plays an essential role for establishing a sustainable energy supply in the near future. The PV production capacity and the installed power have grown strongly in recent years, for example an additional power of 3.8 GW was installed in Germany in 2009 and for 2010 one expects more than 5 GW. Along with this growth a continuous cost reduction has been achieved. However, still a further reduction is necessary to reach “grid parity”, i.e. the cost which the end-user pays for electricity. The key factors for that are Research and Development to increase the efficiency and the throughput as well as a higher production capacity. Today different PV technologies are on the market. These include mono- and multi-crystalline Silicon flat plate modules, thin film technologies (like a-Si, μSi-a-Si, CIS, CdTe), III-V solar cells, organic and dye solar cells. All these technologies have specific advantages and particular fields of application. Yet, the highest efficiency of any photovoltaic device has been realized with III-V multi-junction solar cells, which have recently surpassed the 40% mark under concentrated sunlight. These rather expensive devices, which are today’s standard for the power source of satellites in space, are now also entering the terrestrial market. This is enabled through the use of a perfect partner: concentrating optics. 2. III-V Multi-Junction Solar Cells The basic task of a photovoltaic device is to transform light of the solar spectrum into electrical energy. The part of the spectrum that can be used by a conventional single-junction solar cell is determined by the bandgap of its semiconductor material. Light with energies below the bandgap is lost. The idea of a multi-junction solar cell is now to stack several solar cells with increasing bandgaps on top of each other in order Fig.4: Field installations of a CPV system from Concentrix Solar. [Courtesy: Concentrix Solar GmbH] to exploit a larger part of the solar spectrum (see Fig. 1). III-V semiconductor compounds are the perfect material for this task due to the possibility to vary the bandgap. For the choice of the bandgaps to be used a central design aspect needs to be considered: As the subcells are stacked directly on top of each other and are thus series connected, the device current is limited ultimately by the smallest current generated by one of the subcells. Thus, semiconductors should be chosen in a way that each subcell generates a similar current. Simulations at Fraunhofer ISE showed that a triple-junction solar cell with subcells made of Ga0.35In0.65P, Ga0.83In0.17As and Ge is a very promising design. However, as the semiconductors in the two upper cells do not have the same lattice constant as the Ge substrate it is difficult to grow the III-V semiconductor layers with a high crystal quality, since at the interface of materials with different lattice constants strain is present that results in the creation of dislocations and other crystal defects. Fraunhofer ISE has succeeded in overcoming this obstacle by applying a trick called metamorphic growth. With this concept it is possible to localize the defects in a LIGHTING AND ENERGY 43 region of the solar cell that is not electrically active. As a result, the active regions of the solar cell remain relatively free of defects – a prerequisite for achieving the highest efficiencies. By choosing the metamorphic Ga0.35In0.65P/Ga0.83In0.17As/Ge material combination, a solar cell structure could be chosen for the first time that is completely current matched under the terrestrial solar spectrum. This is what makes the structure very efficient for solar energy conversion and has lead to an efficiency value of 41.1% at a sunlight concentration factor of 454 – a world record in 2009 (see Fig. 2). In addition, the metamorphic crystal growth now enables the use of a much larger range of III-V compound semiconductors for growing multi-junction solar cells. Several groups worldwide have developed a high number of different designs for III-V multi-junction solar cells in terms of the number of subcells and semiconductors used. However, due to the technical complexity and the expensive materials used III-V multi-junction solar cells are rather expensive compared to conventional single-junction solar cells. In order to benefit from their high efficiencies another trick is used: The multi-junction solar cells are placed in concentrating optics. 3. Concentrator Optics In High-Concentrating Photovoltaic (HCPV) systems concentrating optics like mirrors or lenses are used to focus the light on very small solar cells. Concentration factors of up to 1000 are realized. Here the concentration factor is defined as ratio of the aperture to the active cell area. Thus the required expensive semiconductor area is significantly reduced compared to flatplate modules. This enables the use of III-V multi-junction solar cells in terrestrial applications. One of the CPV concepts available on the market is the FLATCON® concentrator module developed at Fraunhofer ISE and commercialized by Concentrix Solar GmbH. The concentrator module uses a Fresnel lens to concentrate the sunlight by a factor of 500 on a small solar cell, which is placed on a copper plate to enable passive cooling (see Fig. 3). The modules are positioned on a two-axis tracker, which assures that the solar cells are in the focus of the lenses throughout the day (see Fig. 4). The high efficiency of the III-V multi-junction solar cells used in this concept is one of the key aspects that lead to high operating AC efficiencies of around 25% for the CPV system. The most promising application for CPV systems are solar power stations with 1 to 100 MWp in countries with a large fraction of direct solar radiation. In these applications the perfect match of highly-efficient III-V multi-junction solar cells and concentrating optics are expected to lead to cost-competitive production of electrical energy. Fraunhofer Institute for Solar Energy Systems ISE Dr. Andreas Bett Heidenhofstr. 2 D – 79110 Freiburg Phone +49(0) 761 - 4588 - 5257 Mail andreas.bett@ise.fraunhofer.de Web www.ise.fraunhofer.de Fig. 1: Sketch of a III-V triple-junction solar cell. The subcells are interconnected with tunnel diode. Each subcell uses a different part of the solar spectrum. Fig. 2: Photo of a solar cell made of Ga0.35In0.65P/ Ga0.83In0.17As/Ge with a cell area of 5 mm², which reached an efficiency of 41.1% under concentrated sunlight. Fig. 3: Sketch of the core of the FLATCON® concentrator module used by Concentrix Solar: A Fresnel lens concentrates the sunlight on a small solar cell. NEW DIMENSIONS AND CURRENT SOLUTIONS IN PHOTONICS 44 Quantum Optics – Optics and Photonics at the Doorsill of Quantum Technology D. Meschede, Professor of Physics, Institut für Angewandte Physik, Universität Bonn 50 years ago, the world’s first laser was operated. It set off a technological revolution which is not yet completed and continues to let optical technologies enter ever more domains of our daily life. Laser radiation allows us to concentrate light very efficiently in time and space. The corresponding concentration of energy gives rise to important applications such as gentle eye surgery or high density optical data media. Also, today’s world-wide communication is impossible without optical fibre links. In short, 21st century photonics seems to rival electronics in its impact on our societies. But there is something else: Quantum optics, exploiting the quantum properties of light and now knocking at the door of technological applications. The quantum signature of light becomes apparent with the observation of photons, the elementary quanta of energy that material samples can absorb or emit. The quantum properties of light, its truly photonic, granular character, were explored and studied as soon as the laser existed. One important reason for its technological relevance is that even single photons can be detected and discriminated with excellent efficiency. And photons have quantum properties that can be manipulated with conventional optical devices such as polarizers. As a result, photons are today probably the best studied and most widely applied quantum objects at all. They are furthermore the ideal means to manipulate “the other” quantum objects we know, including stored atoms, ions, or solid state systems acting as artificial atoms. Over the last two decades, research in atomic and optical physics has dramatically changed our view of the quantum world: We have learned to understand the role of random quantum processes sufficiently well to proceed to the world of quantum engineering, where quantum devices evolve in a completely controlled way but still take advantage of the inherent randomness of quantum processes. An example is the so-called quantum key distribution: Pairs of photons which are individually unpolarized, but have correlated polarizations, are shared by two nodes A and B of a network. Any individual polarization measurement gives random results, e.g. horizontal (H) or vertical (V). The joint measurements, however, are strictly correlated, yielding e.g. HH or VV only. Such correlations can be used to encipher and transmit information faithfully from one node to the other while warranting that no eavesdropper can decipher the keyed message. Elementary quantum objects look like bits, the elementary carriers of information: The polarization states “H” and “V” of a photon may be associated with the “0”s and “1”s of our ubiquitous information devices. Quantum bits or qubits are the quantum analogue of classical bits, and their new aspect is the option to create quantum superposition states. Two qubits can contain the numbers 0, 1, 2, and 3 in parallel, while two classical bits can represent only one of the four. 20 years ago the mathematician Shor discovered that quantum algorithms acting on such arrays of qubits would allow us to perform calculations that no conventional computer could carry out. The vision of the Fig. 1: The blue stream represents a matter wave of atoms (“atom laser”) which is coupled out of a reservoir of ultracold Rubidium atoms. Courtesy N. Spethmann, Universität Bonn. EMERGING TECHNOLOGIES 45 Fig. 2: Bottle shaped microresonator for light with a diameter of about 36 µm (scale bar: 30 µm) made from an optical fibre. The light beam is confined by total internal reflection and can oscillate up to 100 million times between the two outer turning points. The green fluorescence is caused by doped Erbium atoms. Courtesy A. Rauschenbeutel, Universität Mainz. quantum computer was born and has since inspired physicists, mathematicians, computer scientists, and others to strive for this goal. The quantum computer is probably the most beautiful, promising, and not surprisingly also the technologically most challenging aspiration of quantum technology. The key to the future realization of a quantum computer is the control of light matter interactions at the single photon-single atom level. Laboratories around the world are working towards this goal. They find that the methods to tightly control the propagation, absorption, and emission of light by microscopic samples of matter are opening new horizons also for other applications. Intense research has for instance been devoted to the creation of single photon sources. The concept is simple: A (potentially artificial) atom can only emit a single photon at a time. By repeated excitation of this atom a deterministic single photon source is established. Quantum repeaters are an example for what real world applications of quantum technology will require: Today, quantum key distribution is limited to transmission ranges below 100 km because of the inherent attenuation by optical fibre links. The classic method of long distance communication, repeater amplifiers, cannot be used in the quantum world, because amplifiers would destroy the fragile quantum information carried by the photons. The quantum repeater thus actively creates quantum correlations between adjacent quantum channel, to transmit quantum information over larger distances. The requirement: quantum memories where the information propagating from adjacent channels can be received, stored and manipulated – an elementary quantum processor. Several technological developments are contributing to, and profiting from, the emergence of quantum technologies: Laser cooling in the 1980s gave access to trapped ultracold atoms and ions; stored ions will soon be replacing current atomic clocks and lead to improved time-keeping devices for e.g. navigation and networking applications; atomic matter waves (“atom lasers”, Fig. 1) give rise to a new generation of quantum sensors for gravitational and rotational effects; microstructuring of optical components, e.g. micro resonators (Fig. 2) will merge quantum optical technologies with other lines of miniaturized technology. In summary, quantum optical concepts and devices have the prospect of bringing quantum effects, once considered a curiosity beyond our intuition, to technological applications. Prof. Dr. Dieter Meschede Universität Bonn Institut für Angewandte Physik Wegelerstraße 8 D – 53115 Bonn Phone +49(0) 228 - 733477 - 78 Mail meschede@iap.uni-bonn.de Web www.agmeschede.iap.uni-bonn.de NEW DIMENSIONS AND CURRENT SOLUTIONS IN PHOTONICS 46 Photonic Metamaterials: Optics Starts Walking on Two Feet In about every optics textbook, the reader is informed early on that the magnetic response of electromagnetic materials at optical frequencies is pretty much negligible. This limits the possibilities of optics. In fact, half of optics has been missing as mankind has only been able to directly control the electric component of the electromagnetic light wave inside of natural materials – but not the magnetic component. Following the ideas of Sir John Pendry and others, artificial materials called metamaterials can enable an effective magnetic response by densely packing sub-wavelength sized electromagnets called split-ring resonators (SRR) into an effective material. A SRR is simply a metallic ring with a slit (Fig.1). It can be viewed as a miniature LC circuit that leads to a resonance wavelength that is roughly an order of magnitude larger than the diameter of the ring. Thus, operation wavelengths of 1 μm and below require feature sizes of some tens of nanometers. Meanwhile, a variety of corresponding planar structures has been realized via electron-beam lithography [1,2], even including first visible negative-index metamaterials [3]. However, electron-beam lithography is of limited use for fabricating truly three-dimensional structures. Optics itself comes to the rescue in the form of direct laser writing (DLW), which can be viewed as the three-dimensional analogue of electron-beam lithography. Using very tightly focused femtosecond laser pulses and two-photon absorpFig.1: Scheme of a magnetic gold split-ring resonator (SRR) that can be viewed as a miniature LC-circuit [1]. Prof. Dr. Martin Wegener Karlsruhe Institute of Technology (KIT), Institute of Applied Physics, Institute of Nanotechnology, and DFG-Center for Functional Nanostructures and Nanoscribe GmbH tion, essentially arbitrary three-dimensional photoresist structures can be made. With commercially available instruments (see, e.g., www.nanoscribe.de), lateral feature sizes down to about 100 nm can routinely be fabricated today. In what follows, we briefly discuss two recent examples, namely three-dimensional gold-helix metamaterials [4] and three-dimensional invisibility cloaks [5]. Metamaterials are often associated with negative refractive indices and/or “perfect lenses”. However, there is much more to metamaterials and negative indices may not lead to any actual optics products within the next decades. Thus, it is interesting to ask whether other applications taking advantage of the newly acquired magnetic control can be found. Chiral helical metamaterials represent an early example [4]. A three-dimensional helix can be viewed as an elongated version of a SRR (Fig.2). In fact, it is just a magnetic coil into which the light field can induce an electrical current that can lead to a local magnetic field parallel to the incident electric field of the light. Due to the obvious handedness of the helices, coupling to the light field is very different for left-handed circularly polarized light and right-handed circularly polarized light, respectively. Furthermore, it turns out that the spectral response of the helices is rather broadband, covering more than one octave. A corresponding structure made via DLW and subsequent electroplating is shown in Fig.3. Measurements and numerical calculations [4] have shown indeed that one circular polarization of light is nearly completely transmitted, EMERGING TECHNOLOGIES 47 whereas the other circular polarization is blocked (mainly reflected). Thus, this structure can be applied as a compact and broadband circular polarizer – quite in analogy to the good old wire-grid linear polarizers that are frequently used in Fourier-transform spectrometers in many spectral regimes. Further possibilities arise for spatially inhomogeneous metamaterials. The concepts of transformation optics allow for mapping desired but fictitious distortions of spacetime (like in General Relativity) onto actual Cartesian space with locally tailored optical properties. In essence, one shapes optical space rather than real space (in analogy to optical path length and geometrical path length). Generally, this again requires control of both the electric as well as the magnetic component of light to ensure that the wave impedance equals the vacuum impedance to avoid undesired reflections of light. One fascinating benchmark examples for the far-reaching concepts of transformation optics are invisibility cloaks, where light is guided around a region in space that subsequently becomes invisible. In the so-called carpet cloak geometry [5], one even gets away with only a control of the local isotropic refractive index. Fig.4 schematically shows that this index variation can be realized by a local variation of the volume filling fraction of a dielectric woodpile photonic crystal used in the longwavelength limit. Optical microscopy on structures fabricated via DLW has demonstrated the first three-dimensional invisibility cloaks indeed [5]. [1] S. Linden, C. Enkrich, M. Wegener, J. Zhou, T. Koschny, and C.M. Soukoulis, Magnetic response of metamaterials at 100 THz, Science 306, 1351 (2004) [2] G. Dolling, C. Enkrich, M. Wegener, C.M. Soukoulis, and S. Linden, Simultaneous negative phase and group velocity of light in a metamaterial, Science 312, 892 (2006) [3] C.M. Soukoulis, S. Linden, and M. Wegener, Negative refractive index at optical wavelengths, Science 315, 47 (2007) [4] J.K. Gansel, M. Thiel, M.S. Rill, M. Decker, K. Bade, V. Saile, G. von Freymann, S. Linden, and M. Wegener, Gold helix photonic metamaterial as broadband circular polarizer, Science 325, 1513 (2009) [5] T. Ergin, N. Stenger, P. Brenner, J.B. Pendry, and M. Wegener, Three-Dimensional Invisibility Cloak at Optical Wavelengths, Science 328, 337 (2010) Prof. Dr. Martin Wegener Karlsruhe Institute of Technology Institut für Angewandte Physik Institut für Nanotechnologie and DFG-Center for Functional Nanostructures (CFN) Wolfgang-Gaede-Strasse 1 D – 76131 Karlsruhe Phone +49(0)721 - 608 - 3400 Mail martin.wegener@kit.edu Web www.aph.kit.edu/wegener/ Fig.2: Continuous transition between a SRR and a metallic helix [4]. Fig.3: Gold-helix metamaterial made by direct laser writing and electroplating with a lattice constant of 2 µm. This structure can be applied as a compact infrared circular polarizer with one octave bandwidth [4]. Fig.4: Scheme of a three-dimensional invisibility cloaking structure that has actually been made by direct laser writing [5]. NEW DIMENSIONS AND CURRENT SOLUTIONS IN PHOTONICS 48 Ultrashort Lasers that Probe Deep inside Matter Marc Vrakking In the 50 years since the discovery of the laser, the development of sophisticated laser systems accessing novel parameter regimes and the use of these lasers in fundamental research have gone hand in hand and developed symbiotically. Laser development has sparked the emergence of new research fields, and demands from fundamental research have often provided the motivation for the development of novel laser systems. This is certainly also true for one of the latest research fields to make its appearance, so-called “attosecond science”, where light pulses with – currently – a duration as short as 80 attoseconds (1 as = 10 -18 s) are used to observe and control the motion of electrons inside atoms, molecules and in the condensed phase. Attosecond science has its roots in high intensity laser physics, where, late in the 1980’s, it was observed that atoms exposed to intense laser fields can emit radiation in the extreme ultra-violet (XUV) or – even – soft x-ray wavelength range. This emission process, termed “highharmonic generation” because of the characteristic frequency spectrum of the XUV light that consists of odd multiples of the driver laser frequency (see Figure 1), was soon thereafter understood Figure 1: Photoelectron momentum map resulting from ionization of Ar atoms by a high-harmonic laser beam, showing a series of concentric rings due to the fact that the harmonic photons have a frequency that is an odd multiple of the near-IR Ti:Sapphire driver laser frequency Figure 2: The three-step model of high-harmonic generation in terms of a three-step mechanism: electrons are first extracted from an atom by means of strong field ionization, are accelerated in the laser field and then driven back towards the ion that was left behind, setting the stage for a recombination process that is accompanied by photon emission (see Figure 2). A salient feature of this mechanism is that it predicts that the first ionization step is not continuous, but rather occurs only in very short, attosecond time-scale bursts around the peaks of the electric field of the intense driver laser. From this it naturally follows that the XUV radiation is not continuous, but occurs in bursts that are much, much shorter than the optical period of the driver laser, which, for the popular Ti:Sapphire laser, itself is only 2.5 femtoseconds long (1 fs = 10 -15 s). The first attosecond laser pulses were demonstrated in 2001, and since then attosecond science has developed explosively, with dozens of research groups around the world joining the field. European research groups have led the way, with German research institutions occupying a very prominent role. Attosecond pulses are the required tool for studies of electron dynamics on its natural timescale. Therefore, since 2001, they have been used to investigate EMERGING TECHNOLOGIES 49 Figure 3: Left-right asymmetry of D+ fragments resulting from two-color XUV+IR dis- sociative ionization of D2 as a function of the fragment kinetic energy and the delay between the XUV and IR pulses, revealing two mechanisms that control the localization of the single electron in a D2+ molecular ion technology in surface sciultrafast atomic proence. On the other hand, cesses, such as Auger the development of high decay, strong-field ionpulse energy driver lasers ization, shake-up pro(with instantaneous powcesses accompanying ers reaching well beyond ionization, and several the TWatt level (1 TWatt more, to observe elec= 1012 Watt) by extending tronic re-arrangement inside molecules and current Ti:Sapphire-based to measure, in real chirped pulse amplification time, photo-emission schemes and by developprocesses at surfaces. ing Optical Parametric Figure 3 shows a very Chirped Pulse Amplifiers recent result, where a (OPCPA), will enable the full left-right asymmetry Figure 4: exploration of attosecond Elements of an attosecond laser laboratory, including a setup technology in attosecond was observed in the for high-harmonic generation and several detection chambers pump-attosecond probe production of D+ fragexperiments, while at the ments in dissociative same time allowing the development of powerful sources ionization of D2 molecules by an attosecond laser pulse, for diffractive XUV imaging. For a range of applications, pointing towards two mechanisms that lead to a localizaharmonics-based XUV sources may represent a laboratorytion of the electronic charge distribution in the molecule, scale alternative to the use of free electron lasers. i.e. chemistry on attosecond and few-femtosecond timesThe development of high-average power lasers for attocales! second science offers the potential for important industrial Already, during its brief history, attosecond science spin-offs, such as the use of high repetition rate short-pulse has provided the impetus for significant new laser developlasers in laser machining. Already, the new attosecond laments, such as the development of carrier-envelope-phase ser laboratory that was recently established at the Max (CEP)-stable laser amplifiers that facilitate the controlled Born Institute in Berlin has started exploring these posgeneration of isolated attosecond laser pulses, and that sibilities, and important opportunities for the application of parametric amplifiers operating in the mid-infrared waveof lasers that were first developed for attosecond science length regime that allow to push the energies of the generin the manufacturing of solar cells have been identified. ated photons towards the x-ray regime. Important targets for the future are the development of high average power carrier-envelope phase-stable few-cycle driver lasers, with two distinguishable variants. On the one Prof. Dr. Marc Vrakking hand, high average power (tens of Watts) MHz lasers will Max-Born-Institut Max-Born-Straße 2A allow to significantly extend the KHz experiments that are D – 12489 Berlin currently performed, paving the way for the use of sophistiPhone +49(0)30 - 6392 - 1201 cated detection strategies borrowed from the synchrotron Mail marc.vrakking@mbi-berlin.de community as well as the extensive use of attosecond Web mbi-berlin.de NEW DIMENSIONS AND CURRENT SOLUTIONS IN PHOTONICS 50 Ultra-short Laser Pulses for 3D Patterning – Enabler for Optical and Life Science Applications Ruth Houbertz Fraunhofer ISC, Würzburg I. General aspects Optical technologies cover a broad range of applications which make use of the generation and the manipulation of light, and they open up a wide field of novel applications when combined with electronics or (bio-)medicine. Since the invention of the laser in 1960 [1], many efforts have been made to develop laser light sources in order to continuously increase their application potential. Nowadays, lasers are employed in industry, communication, consumer electronics, and research and development. With the postulation of two-photon absorption in 1931 [2] and the invention of ultra-fast lasers which led to the experimental demonstration of this effect in 1997 [3], many different applications were addressed, and the interaction of ultra-short laser pulses with polymer or glass materials is of high technological interest. Non-linear absorption initiated by focusing ultra-short laser pulses into materials are particularly used for the 3D free-form fabrication of functional structures among which are waveguides [4], metamaterials [5], or scaffold structures [6,7] for biomedical applications. Since the triggered reactions are strongly confined to the focal region, the fabrication of 3D microstructures is performed simply by moving the focal volume in 3D through the materials. The appeal of the method is that it provides a scalable technology, whereas most of the structures which were demonstrated so far are in the range of only several 100 μm with some examples of waveguides which were written on a several cm scale in length [4]. The generation of complex free-form 3D structures in custom-designed multifunctional materials such as inorganic-organic hybrid polymers (ORMOCER®s) is beneficial for many applications [7], combining the design possibilities of 3D fabrication with the power of multifunctional materials. Not only the material’s optical and electrical properties can be tailored, but also their thermal and mechanical properties. Additionally, suitable functionalization creates binding sites for, e.g. biomolecules and cells in order to also enable micromedicine and biomedical applications. II. Integrated optical interconnects The continuous requirement of an increasing performance of microelectronic devices is nowadays also associated with a strong demand for optical interconnects, particularly on board level. Integrating optical interconnects in printed circuit boards (PCB) is a rapidly growing field due to a continuously increasing demand for high data rates, along with a miniaturization of devices and components, making this technology very attractive for backplane or mobile applications. This is related to the fact that optical data transfer is highly superior to electrical data transfer concerning data rate, transmission distance, bandwidth-length product, electromagnetic interference resistance, and weight. In addition, the interconnect density in optics can be much Figure 1: (a) Innovative integration schematics of a pre-configured optoelectronic PCB, and (b) TPA-written waveguides (cross-section) in ORMOCER® ( = 800 nm) (after [4]). (a) (b) EMERGING TECHNOLOGIES 51 higher compared to Cu technology. For high-speed data transfer, materials and integration concepts are needed which account for miniaturized high-speed short-range connections, low costs, and which - preferably - enable free device design. A prominent example is the direct fabrication of waveguides for data communication at 850 nm in PCB by using just one specially tailored hybrid polymer material processed on a pre-configured PCB (Figure 1 (a)). By focusing femtosecond laser pulses into the bulk of the ORMOCER® layer, organic cross-linking of the organically modified inorganic-oxidic oligomers is initiated by twophoton absorption (TPA) in the focal region forming the In order to demonstrate the power of the TPA technology for the production of scaffolds, the experimental setup for the TPA patterning was modified at Fraunhofer ISC to allow the fabrication of (high resolution) large-scale structures with structure heights being not limited by the used optics. This enables the fabrication of scaffold structures as well as of human ossicles (Figure 2). IV. Challenges for market introduction of the technology TPA technology up to now has not reached the market as a mainstream manufacturing technology. Apart from the ongoing development and optimization work in materials, this is mainly due to the lack of availability of veritable manufacturing grade TPA (a) (b) equipment. Current sizes of structures manufactured with TPA on lab-scale equipment are in the mm range. Recent developments by Fraunhofer ISC yielded manufacturingcompatible equipment that is capable of reliably producing large-scale scaffolds. This exciting development is a major stepping stone towards the manufacturing of continuous structures measuring several cm in any direction. Figure 2: (a) Scaffold structure, and (b) human ossicles in life-size, produced by TPA using a custom-designed ORMOCER®. core of a multimode waveguide, while the surrounding hybrid resin acting as cladding is still liquid. The latter is subsequently cross-linked by thermal processing in the PCB production process. After that, the refractive index difference between the waveguide’s core and its cladding is still high enough to account for data rates of about 7 Gb/s at a bit error ratio (BER) of about 10-9. Due to the intrinsically high mechanical and chemical stability of the hybrid polymers, this material class can be used to demonstrate the potential of TPA processes to be up-scaled from the sub-μm regime to the cm regime. Examples are given in Figures 1 and 2. III. Scaffolds for regenerative medicine Presently, the use of TPA was mainly demonstrated on a smaller length scale with structural dimensions of only a view hundreds of μm, and a typical resolution down to 100 nm. For (bio)medical or tissue engineering applications, other requirements need to be fulfilled. These are, for example the fabrication of large-scale 3D scaffold structures which provide interconnecting pores or channels for growing cells, which can be decomposed by the body, and which will enable an up-scaling to several cm in size [7]. At the same time, the reduction of the fabrication time of these scaffolds is still very challenging with respect to process and materials. V. References [1] T.H. Maiman, Nature 187 (1960) 493. [2] M. Göppert-Mayer, Ann. Phys. 401 (1931) 273. [3] S. Maruno, O. Nakamura, and S. Kawata, Opt. Lett. 22 (1997) 132. [4] R. Houbertz, V. Satzinger, V. Schmid, W. Leeb, and G. Langer, Optoelectronic printed circuit board: 3D structures written by two-photon absorption, Proc. SPIE 7053 (2008) 70530B.1 [5] T. Ergin, N. Stenger, P. Brenner, J. B. Pendry, M. Wegener, Science 16 (2010) 337. [6] A. Doraiswamy, T. Platz, R.J. Narayan, B. Chichkov, A. Ovsianikov, R. Houbertz, R. Modi, R. Auyeung, and D.B. Chrisey, Mat. Res. Soc. Symp. Proc. 845 (2005) AA2.4.1. [7] Th. Stichel, B. Hecht, R. Houbertz, and G. Sextl, Laser Precision Micromachining (LPM), #10-29, Stuttgart, June 2010. [8] http://www.isc.fraunhofer.de Dr. Ruth Houbertz Fraunhofer Institute for Silicate Research Neunerplatz 2 D – 97082 Würzburg Phone +49(0) 931 - 4100 - 520 Mail ruth.houbertz@isc.fraunhofer.de Web www.isc.fraunhofer.de NEW DIMENSIONS AND CURRENT SOLUTIONS IN PHOTONICS 52 Forum Organic Electronics: Innovation and Growth in a Green Environment Dr.-Ing. Michael Kröger InnovationLab GmbH Organic Electronics for a Green Environment Organic Electronics is maturing from a promising, but future technology into a current multi-billion-dollar plastic semiconductor industry. Applications for organic electronic materials range from organic light emitting diodes (OLED) for general lighting and displays and organic photovoltaic (OPV) cells for power generation to organic thin film transistors (OFET) for item tagging and organic sensor applications (OSA) for supply chain control. Most of these applications will contribute to preserve nature by enabling a CO2 free energy conversion and to reduce energy consumption by simultaneously offering fascinating new applications. Organic light emitting diodes for general lighting are significantly more efficient than incandescent bulbs and will also surpass compact fluorescent light sources. Organic photovoltaic cells with a three times higher energy yield can be printed and so lead to substantially lowered production costs for solar energy conversion which will make these devices not only environmentally but also economically favorable. Still, there are technological challenges to be solved to make organic electronics an everyday-and-everywhere technology. To solve these challenges very different and widespread fields of expertise need to be addressed, which among others include molecular design and synthesis, thin film processing and printing technology, device and systems design. To finally succeed, co-development and co-innovation are crucial conditions. Leading-Edge Cluster Forum Organic Electronics Forum Organic Electronics is a Leading-Edge Cluster centered in the German Rhine-Neckar Metropolitan Region and combines the scientific excellence and economic strength of its academic and corporate partners to establish the world leading centre for White OLED organic electronics. The partners’ netdemonstrator work includes 3 DAX-noted and 7 interas used for lighting applications. nationally involved enterprises, 6 mid©BASF dle-sized businesses and 9 universities respectively research institutions. These partners operate at complementary positions along the value chain which ranges from the design and synthesis of novel materials, the research on next-generation devices, the development of inexpensive processing technology and production systems - especially printing technology- and finally the marketing of breakthrough applications and services. In 2008, the cluster was awarded as a Leading-Edge Cluster with € 40 million by the German Ministry of Education and Research. This public funding is multiplied by the industrial cluster partners and is directed towards application-oriented R&D projects. ORGANIC ELECTRONICS 53 InnovationLab: A Unique Cooperation between Business and Science As the vital strategy tool of the cluster, the universities of Heidelberg and Mannheim and the leading industrial partners BASF SE, Freudenberg & Co. Kommanditgesellschaft, Heidelberger Druckmaschinen AG, Merck KGaA, Roche Diagnostics GmbH and SAP AG have jointly founded InnovationLab GmbH (iL) based at Heidelberg. iL is an application oriented research and transfer platform of business and science with the common goal of driving innovation and serves its partners in two ways: 1. iL executes the cluster management for Forum Organic Electronics. On the inside, iL is seen as a nexus for the exchange of ideas and information. Regular on-site Heidelberg R2R pilot line. © Heidelberg strategy meetings with industry leaders, A scientist inspects organic solar cell test devices. © BASF cluster conferences and a seminar series with internationally renowned speakers are organized. Further, iL promotes technology entrepreneurs and talented researchers at early career stages in several different training programs. To the outside, iL represents a communication hub towards funding agencies, non-cluster industry and academia partners, other international research centers and the public media. 2. iL operates a common research facility for cross-industry/cross-academia collaboration. In 2010, iL opened a world-class clean-room laboratory for device and process development and extensive auxiliary laboratories for materials synthesis and characterization. The laboratory is used by iL and its industrial and academic partners for joint research on organic and printed electronics. The open innovation approach, some of the most prestigious senior scientists in the field allows an efficient utilization of the cluster’s resources, of organic electronics, which installed smaller research shorter communication paths and faster innovation groups led by young and talented postdoctoral researchcycles. The clean-room laboratory is equipped with ers. Application-relevant IP created by these groups will several small to large scale printing and solution coatbe transferred into close-to-market projects and will either ing machines and several vacuum systems for device be spin off or sold to industry partners. iL welcomes new fabrication and materials characterization and analysis partners to join the research network and to collaborate in (e.g. XPS). The printing tools can handle substrates common projects. sizes in the range from less than one inch for proofof-concept and materials characterization to letter-size for large area prototyping and km-long foil substrates Dr. Michael Kröger within a R2R pilot line. Research at iL is organized in 5 different competence centers: synthesis, printing technology & device physics, simulation & modeling, morphology and analytics. To direct the research within the competence centers, iL has won InnovationLab GmbH Speyerer Straße 4 D – 69115 Heidelberg Phone +49(0) 6221 - 54 19 122 Fax +49(0) 6221 - 54 19 110 Mail michael.kroeger@innovationlab.de Web www.innovationlab.de NEW DIMENSIONS AND CURRENT SOLUTIONS IN PHOTONICS 54 Printed Electronics – Process and Products Dr. Walter Fix The idea of manufacturing integrated circuits by means of printing technologies has fascinated researchers and developers since the late 1990s. Electronics being printed like newspaper, in large quantities opens up entirely new areas of application for micro-electronics: from radio-operated labels for replacing the optical barcode to intelligent packaging and smart objects for processing and displaying information. The trend towards highly cost-efficient electronics which is simultaneously available in great numbers ultimately leads to printed electronics, since there is no structuring or layering process that is faster than printing. The objective of printed electronics is to create new mass markets for cost efficient electronics, without attempting to compete with silicon electronics, which would be a hopeless endeavour anyway. In order to realize roll-to-roll printed electronics several key requirements have to be met. For high volume fabrication a low cost semiconductor material with sufficiently high electrical performance has to be available in large quantities and with reproducible quality. In addition high speed printing processes as well as electronic circuit designs have to be adapted to the needs of printed electronics. Last but not least high speed roll-to-roll electrical test equipment needs to be developed to ensure high quality. Fig.1: Layer stack for integrated circuits (a). The high resolution production process allows minimum structure sizes down to 10 µm (b) Dr. Klaus Schmidt At PolyIC a special layer stack for integrated circuits was designed consisting of a lower metal electrode (e. g. silver) followed by an organic semiconductor like P3AT, a special insulating layer and an upper metal electrode for example based on copper (Fig. 1a). With this layer stack transistors, diodes, resistors, capacitors and vias can be realized. In this way more than 10000 m2 of printed circuits can be fabricated each month at a typical web speed of about 30m/min. Since fast transistors need a short channel length, a high resolution process is necessary for printing the bottom electrode. Thus, the lower metal layer of our stack can be used to manufacture transparent conductive films consisting of a mesh of only 10μm wide metal lines (Fig. 1b). Such PolyIC films outperform standard ITO and PEDOT films not only in terms of transmittance but also in terms of conductivity which makes them a good choice for applications like touch sensors, EMI shielding or flexible circuit boards (Fig. 2). Basic elements for more complex electronic circuits are organic transistors. The functionality of organic transistors is very simple and comparable to thin-film transistors (TFT). Fig. 3 shows the principal setup of a printed transistor based on our 4 layer stack process. Without an applied gate voltage (VGS) the current flow between the source (S) and drain (D) electrode is suppressed, since the semiconductor layer is intrinsic and, consequently, non-conducting. Once a gate voltage is applied, a very narrow conductive channel forms at the semiconductor/insulator interface due to the accumulation of charge carriers. Now current flow from the source to drain contact is possible. The current level depends on the gate voltage as well as on the insulating and semiconducting material, respectively. Transistors are the basic elements for more sophisticated electronic circuits necessary for reasonable applications. Based on the full capability of our 4-layer stack fabrication process a 4 bit Manchester chip was not only printed but also tested and analyzed with the PolyIC roll-to-roll manufacturing technique. ORGANIC ELECTRONICS 55 Fig.2: Sheet resistance versus transmittance (without substrate) plottet for PEDOT, ITO, and the PolyIC transparent conductive film. RFID tags are employed for various applications and fields of use: Depending on the customer’s needs, the focus is on anti-theft systems, proof of authenticity, logistics tracking or indicator functions. First pilot products are already tested. Especially item level tagging, i.e. the marking of individual goods, will be an important field of application of this technology. For this reason, the 96-bit electronic product code™ is being developed as the replacement for the optical bar code. The prospect of being able to print electronics directly onto products or their packaging is even more visionary. The technical challenges that still exist are, however, also related to manufacturing aspects, given that the tagging of low value mass products should not notably increase their price. The chip consists of numerous building blocks: a rectifier, a ring oscillator with 15 stages as the clock generator, a counter with 3 flip-flops, a protocol generator for Manchesterencoded data signals, and a readonly memory. Fig. 4a shows the block diagram of the chip. In Fig. 4b the measured signals, including the clock, the counter, the data sequence of the code generator and the load modulated rectifier signal is depicted. Fig. 4 clearly demonstrates that all printed complex electronic devices can be realized. Fig.3: Transistor structure in top gate geometry Fig.4: Block diagram of the printed 4-bit Manchester-encoded chip. The signals measurement at the four labeled measuring points are shown in below. In conclusion the technology of printed electronics opens up a vast field of novel electronic products. If the expectations regarding price and performance are met, the vision of electronics that are available everywhere could become true. Polymer electronics will not bring forth new supercomputers, but it will contribute to new products in the field of intelligent packaging and electronic paper, all the way to plastic chips in shirts and on yoghurt cups. However, there are still several problems to solve in order to realize this electronic revolution. A particularly important aspect is the physical understanding of polymer transistors, especially in terms of charge transport in polymer layers and the influence of interfaces on the transistor characteristics. Additionally, an extensive collaboration between physics, chemistry and printing technology is required, in order to transfer the high-performance circuits from the laboratory to a roll-to-roll printing processes. PolyIC GmbH & Co. KG Dr. Walter Fix Tucherstrasse 2 D – 90763 Fürth Phone +49(0) 911 - 20249 - 8111 Mail info@polyic.com Web www.polyic.com NEW DIMENSIONS AND CURRENT SOLUTIONS IN PHOTONICS 56 Roll to Roll Fabrication of OLED Lighting Devices Dr. Christian May Head of Business Unit OLED Lighting and Photovoltaics at Fraunhofer IPMS In recent years Dresden has evolved into a research center for organic materials and systems. In order to transfer the results to production further improvements in the production process and the establishment as well as the testing of first pilot-production lines are necessary. That is why a Center of Organic Materials and Electronic Devices Dresden (COMEDD) was founded at the Fraunhofer Institute for Photonic Microsystems IPMS. COMEDD combines research and development works for the production, integration and technology of organic devices. The mission of COMEDD is the customer and application specific research, development and pilot production of novel device concepts and production methods for vacuum deposited organic materials. Within COMEDD a roll-to-roll line for research and development for OLED lighting is currently going into operation. Several roll-to-roll equipment is available for different kind of evaluations. A vacuum deposition system (fig. 1) is available for evaporation of organic materials (small molecules) and metals. The attached 14 organic linear evaporators (5 double, 4 single) are able to realize a white pin OLED with high efficiency and other organic devices like solar cells. The winding concept of the roll-to-roll coater avoids front side contact of the substrate to the transport rollers. After the coating process the web can be protected during the rewinding by a liner foil. The deposition cylinder can be heated up to 80 °C for substrate pretreatment and can be actively cooled down to -10 °C during the deposition process. A coating and lamination unit is suited for functionalizing the substrate surface by coating processes and Smoothing the way for economic flexible OLEDs Organic light-emitting diodes (OLEDs) are nowadays synonymous with next generation lighting, which could replace common light-bulbs in a couple of years. However, existing OLEDs on the market are costly and mostly deposited on rigid materials such as glass. The development of flexible, organic light-emitting diodes, which can be manufactured on an industrial scale, promises economies of scale and accordingly broader marketing of the environmentally sound and highly efficient devices. The roll-to-roll process allows high throughput as a significant cost reducing step for organic based devices to penetrate into the general lighting and photovoltaic market. Metal foils as substrate in combination with the pin OLED technology will allow direct OLED deposition on metal foils Fig. 1: Roll-to-Roll Vacuum deposition system for small molecule nased OLEDs with high power efficiency. for lighting applications ORGANIC ELECTRONICS 57 Fig. 2: Electrical test of OLEDs on 200 x 200 mm2 flexible aluminium foil. encapsulation of organic devices with e.g. a barrier foil. The coating and lamination unit is encased in an inertbox to process under protective atmosphere. Therefore printing and coating with moisture and oxygen sensitive materials is possible. Last, but not least an inspection is available consisting of a winding unit with a CCD camera bank for pixel resolution down to 14 μm (100% web inspection) and a modular, moveable optical microscope with a point resolution down to 1 μm. First attempts have been made to fabricate emitter doped stack OLEDs on flexible metal foil in the R2R processing using the systems described. The focus of experiments was adjustment of the processing steps and specific use of the organic linear evaporators (e.g. co-evaporation) to fabricate OLEDs to get stable devices. Finally, the first Fig. 3: Researcher from the Fraunhofer IPMS is presenting a flexible OLED with the new barrier layer system monochrome doped SMOLEDs in R2R processing on flexible metal substrate were successfully realized (fig. 2). Furthermore for the first time a flexible OLED in a roll-to-roll production was manufactured and encapsulated in a subsequent inline-process together with the partner from Fraunhofer Institute for Electron Beam and Plasma Technology FEP (fig 3). It was possible to deposit OLED materials on a cheap aluminum foil in a roll-to-roll pilot plant, further encapsulate the luminescent foil with a barrier layer system without compromising its luminosity. This process design would allow the production in a single plant. The steps were developed in Fraunhofer Institute for Photonic Microsystems IPMS – the frame of the project “Roll-to-roll production of highly efCOMEDD Center for Organic Materials and Electronic ficient light-emitting diodes on flexible substrates”, support Devices Dresden codes 13N8858 and 13N8857), funded by the German Maria-Reiche-Straße 2 D – 01109 Dresden federal ministry of education and research (BMBF). The Phone +49(0) 351 - 8823 - 309 work is going to be continued by the Dresden Institutes in Fax +49(0) 351 - 8823 - 266 a bigger consortium within the BMBF funded project R2Flex Mail christian.may@ipms.fraunhofer.de (http://www.r2flex.de). Web www.ipms.fraunhofer.de Resu fromlts and and Resea Service Insti rch C s tutio lust ers ns RESULTS AND SERVICES FROM RESEARCH CLUSTERS AND INSTITUTIONS 60 The One-Stop for Technology and Innovation made in Berlin Laser Optics Berlin 2010, Source: Messe Berlin GmbH Because of its economic importance and its enormous impact on adjacent areas of technology and user industries, optical technologies and microsystems technology have become a focus of the technology policy of all leading industrial countries. International comparisons have shown that Berlin, with its more than 400 research institutions, enterprises and service providers, has a tremendous potential for the establishment of a globally recognized industry location. This is further underlined by the high density of competence in research and development institutions. This results in a steadily growing need for a rapid transfer of technological knowledge into the economy. Not least because of the varied applications of optical technologies and microsystems technology, support for innovation - all the way from invention to a marketable product - attains crucial importance for a sustainable development of the Berlin scientific and economic location. To promote this process is the objective of the TSB Innovation Agency Berlin. It is the central focal point for technology and innovation in Berlin. It links science, economics and politics in the fields of biotechnology, medical technology, transport and mobility, energy, information and com- munication technology, as well as optical technologies and microsystems technology. Among the traditional tasks of the TSB are cluster management in Berlin's areas of expertise, knowledge and technology transfer, innovation consulting, network initiation and development, project coordination, start-up consulting, and other services such as information services and event management. Within the business area of optical technologies, a particular focus is the publication of industry reports for optical technologies and microsystems technology, which contain detailed information on economic developments, trends in research and industry, as well as profiles and contact details of companies and research institutions in Berlin. In 2010, the TSB published the first report for one of the regional focal point areas within the optical technologies: Laser Technology. Furthermore, the TSB sponsors the Laser Optics Berlin, an international congress and fair for optical technologies and laser technology, which takes place every two years. After the event outgrew its original location - the science and technology park Berlin-Adlershof - in 2008, the Messe Berlin assumed the lead in organizing the event in 2010. With RESULTS AND SERVICES FROM RESEARCH CLUSTERS AND INSTITUTIONS 61 Congress of Laser Optics Berlin 2010. Source: Messe Berlin GmbH 135 international exhibitors and 2.900 visitors, including 450 congress participants, the Laser Optics Berlin showed significant growth despite the continuing economic crisis. the Laser Optics Berlin Congress. With 15,000 members in 95 states it is the world's largest association in the field of optical technologies. Laser Optics Berlin and microsys Berlin under one roof beginning in 2012 The synchronization of the Laser Optics Berlin and the microsys Berlin offers professionals an innovative platform. The representation of the interfaces between optical technologies and microsystems technology are a novelty in the German trade fair market. Micro-optics and micro-optical systems have not previously been exhibited in such a compact and user-oriented form. Following a successful pilot connecting the microsys Berlin in an appropriate manner with the Laser Optics Berlin, this path will be continued and the content will be more focused on the intersection of the two events (such as micro-optics, MOEMS, Laser and LED systems). Utilizing a modified structure, the goal is to increase international appeal and improve presentation of regional capabilities and supra-regional importance. The selection of the papers for the microsys Berlin congress rests in the hands of a separate committee headed by Dr. Klaus-Dieter Lang, director of the Fraunhofer Institute for Reliability and Micro Integration (IZM). OSA Optical Society of America organizes the 2012 Congress One new feature in particular aims to bring the synchronized international trade fair even more into focus: the Optical Society of America will assume the organization of Prof. Dr. Eberhard Stens TSB Innovationsagentur Berlin GmbH Optics Division Fasanenstr. 85 D – 10623 Berlin Phone +49(0) 30 - 46302 - 441 Mail optik@tsb-berlin.de Web www.tsb-optik.de/en RESULTS AND SERVICES FROM RESEARCH CLUSTERS AND INSTITUTIONS 62 Fraunhofer IOSB Profile of the Institute The Fraunhofer Institute of Optronics, System Technologies and Image Exploitation IOSB is very successful in implementing the latest research results in application-ready solutions: both those which represent immediate financial benefit for our customers and those which strengthen their competitiveness for the long-term. The IOSB researches and develops innovative concepts, processes and systems for industry, small and medium-sized enterprises and public sector customers. In so doing, the task, the problem set by the customer is always the starting point and focus for our thinking and action. Core competences The name of our institute reflects our three primary core competences. Two of these are practically self-explanatory: by Optronics we mean electro-optical systems and processes for acquiring signals and images from the ultraviolet to the thermal infrared. Image Exploitation includes preparation, real-time processing and automatic and interactive information extraction from images and videos. The most abstract of the three may at first glance seem to be System Technologies, which represents a cross-section of expertise and is essential if you want to answer difficult, comprehensive questions with holistic solutions. System technologies bring together everything necessary for analysis, understanding, modeling, development and control of complex systems. Business Units As a Fraunhofer Institute, the IOSB has a clear task: to focus its research on application and thus on the needs of businesses and public sector customers. Alongside scientific specialization, a focus on the institute’s customers is also required because the best possible solutions require not only academic and technical expertise but also sound knowledge of industry. The IOSB concentrates primarily on five business units: • automation, • energy, environment, • automated visual inspection, • defense • and civil security. The »Purity« System is made especially for the inspection of transparent materials as green bodies of glass. © Fraunhofer IOSB. RESULTS AND SERVICES FROM RESEARCH CLUSTERS AND INSTITUTIONS 63 Since the beginning of 2010, the IOSB-AST in Ilmenau has been running an underwater robotics centre with a generously sized pool and an experimental energy park, which provide the best research and development conditions for underwater systems and new energy supply facilities. Further examples for technologies of the IOSB are: One example for systems by IOSB is the inspection system PURITY: Purity: Automatic inspection of transparent materials One challenge currently facing industrial image processing is the need to detect inclusions and air bubbles within transparent materials which may be shaped in any variety of ways. The latter include flat glass, curved glass, lenses, balls, granulates and similar objects. The patented Purity system detects and distinguishes changes in transparency, inclusions of foreign objects and air bubbles – virtually irrespective of object shape. In contrast to conventional systems, Purity allows inspection to be performed entirely from a single perspective in most cases. At the core of this flexible, reliable inspection system is either a line camera or laser scanner, depending on the particular task. Images are able to be recorded and analyzed in real time, allowing sorting of materials at flow velocities of up to 3m/s as well as inspection in free fall. Device options Inspection of flat objects, such as granulates, fragments or flat glass, is performed using single or multi-channel systems based on line cameras. Objects which are expanded threedimensionally, such as hollow glass or curved glass are inspected using a single or multichannel laser scanner. In both applications, the first channel is used to determine the transparency profile of the object. This can then be compared with a specified (good) profile. Faults detected in the transparency profile can be the result of deviations in shape, deviations in transmission, embedded foreign objects or surface faults. The type of fault can be determined and classified using additional inspection channels. Alternatively, the color gradient within the item inspected can be checked when inspecting flat objects. White-light generation by femtosecond laser pulses. © Fraunhofer IOSB „Gated Viewing“, system for the automatic tracking of fast objects. © Fraunhofer IOSB Fraunhofer IOSB Prof. Dr.-Ing. Jürgen Beyerer Fraunhoferstr. 1 D – 76131 Karlsruhe Phone +49(0)721 - 6091 - 0 Prof. Dr. Maurus Tacke Gutleuthausstr. 1 D – 76275 Ettlingen Phone +49(0)7243 - 992 - 0 Web www.iosb.fraunhofer.de RESULTS AND SERVICES FROM RESEARCH CLUSTERS AND INSTITUTIONS 64 Solutions with Light – Overcome Challenges and Offer Opportunities Gray scale projection from the static array projector. Static monochrome array projection optics (left), micro-lens array with buried color filters and apertures for the dynamic array projector (right). RGB projection from the dynamic array projector. Together with its partners, the Fraunhofer IOF conducts application oriented research in the field of optical systems engineering on behalf of its clients from industry and of the government. The objective is to develop innovative optical systems to control light, from its generation to its application in the cutting-edge fields of energy, environment, information, health and safety. In this context, the sustainable energyefficient use of light – “green photonics” – plays a special role for the IOF. To achieve these goals, the IOF charts the entire process chain, from optical and mechanical design and the realization of functional optical surfaces and coatings via micro- and nano-structuring as well as system integration up to the manufacture of prototypes optical, opto-mechanical, and opto-electronic systems. The close cooperation with the Institute of Applied Physics (IAP) at the Friedrich Schiller University is of particular strategic importance in both covering the scientific lead work and training young scientists. Ultra-slim array projector The market of miniaturized projectors is a fast growing market. In all current systems of pocket projectors, a single imaging channel is used. This means a minimal size for the projector is a given – and smaller will not work. The novel optics scheme of the array projector enables extremely slim but laterally extended projection systems with large flux. The array projector consists of a regular array of individual projecting channels which form a superposed image on a screen, enabling realization of static as well as dynamic projectors. The static projector consists of a tandem array of micro-lenses of short focal length with a buried mask representing the object array. Flux enhancement requires no enlarged overall length but an increased number of superposed projection channels. Because of the system design similar to a fly´s eye condenser, a homogenization RESULTS AND SERVICES FROM RESEARCH CLUSTERS AND INSTITUTIONS 65 of the illumination source takes place simultaneously with the projection. Channel-wise coloration of images using a buried RGB color filter array permits generation of full-color images. Thanks to the many channels, the construction length of the entire system can be clearly reduced to 3 mm, without impeding luminosity. High-performance LEDs are used as the light source. Nanostructrured SIS solar cells Using sunlight for energy generation preserves natural resources and decreases CO2 emission. The photovoltaic industry faces the challenge of developing efficient cell concepts with low-cost production processes. A requirement highly efficient solar cells have to meet is for the incident radiation to be efficiently coupled into the absorbing material. Nanostructured silicon surfaces are a well-known solution for the generation of broadband antireflection properties as well as direct photon management. To implement low-cost semiconductorinsulator-semiconductor (SIS) systems, a thin film of an insulating material is deposited on silicon, followed by coating with a transparent conductive oxide (TCO), for which indium tin oxide or aluminum doped zinc oxide can be used. The combination of nanostructured silicon interfaces and low-cost SIS systems creates an innovative solar cell concept with the potential of high efficiency at low production costs. First laboratory experiments show an effectiveness of 8 % for up to 6 inch sized nanostructured solar cells. BMBF project PHIOBE (FKZ 13N9669). Ultra-short pulse laser of high average power Today, diode pumped fiber lasers and amplifiers are capable efficiently producing radiation with multi-kilowatt average power in the near infra-red range at diffraction limited beam quality even in ultra-short pulse operation. A milestone was achieved by demonstrating a chirped pulse amplification system with 830 W average power (T. Eidam et. al, Opt. Lett. 35, 2010, 94-96). Therewith efficient laser systems become available for micromachining. The applicability of these high repetition rate systems was demonstrated by drilling experiments with different metals. Fraunhofer-Institut für Angewandte Optik und Feinmechanik IOF Dr. Brigitte Weber Albert-Einstein-Straße 7 D – 07745 Jena Phone +49(0) 3641 - 807- 440 Fax +49(0) 3641 - 807- 600 Mail brigitte.weber@iof.fraunhofer.de Web www.iof.fraunhofer.de Nano-SIS solar cell. SEM micrograph of a NanoSIS solar cell. Compact high performance ultra-fast fiber laser system. Drilled hole in 0.5 mm thick copper with 75 ms breakthrough time. RESULTS AND SERVICES FROM RESEARCH CLUSTERS AND INSTITUTIONS 66 Optics Design – Bridge between New Technologies and Innovative Applications Fig. 1: Highly integrated optical fluorescence module fabricated by ultraprecision micromilling (S. Stoebenau, et al., 10th international conference of the European Society of Precision Engineering & Nanotechnology (EUSPEN), Delft, 31.5.-4.6.2010). Fig. 2: Ultracompact optics module for optical micromanipulation with optimized trapping forces ("A. Oeder, et al., EOS Annual Meeting, Paris, 26.-29.10.2010.") Here at the Ilmenau University of Technology we recognise the importance of innovation and basic research for the development of future micro- and nanosystem technologies with applications in Life Science, Energy Efficiency and Photonics. Accordingly we have made a strategic decision to develop one of the largest centres in Germany for interdisciplinary cooperation in these exciting high-potential areas: The Institute for Micro- and Nanotechnologies (IMN - MacroNano®). This structure allows our varied research groups maintain their expertise and specialization, while simultaneously ensuring cooperation across a broad range of research topics. Examples of successful projects in the area of optical technologies include (i) active optical microsystems using thermally actuated Aluminumnitride membranes and (ii) the integration of optical nanotools into the “Nanopositioning and Nanomeasuring Machine”. These projects were respectively realised with the support of German Science Foundation through funding in the priority programme (SPP 1337) "Active Microoptics" and the Collaborative Research Center (SFB 622). Optical microsystems are an important research topic funded within the “Kompetenzdreieck Optische Mikrosysteme” by the German “Bundesministerium für Bildung und Forschung”. As members of the IMN, we – the Fachgebiet Technische Optik and the Juniorprofessor of Optik Design, Simulation und Modellierung optischer Systeme (funded by the Carl-Zeiss-Stiftung) - are responsible for adapting research in classical optical engineering and lens design into innovative optical (micro) system technologies. We specifically focus on design, integration, tolerancing, fabrication, and characterization of freeform optical elements in optical (micro-) systems. To realise novel prototype systems we rely on our unique fabrication facility that combines both ultraprecision mechanical and laser machining in a single machining centre. Here we have developed many novel freeform elements and systems, e.g. for head-up displays for the automotive industry or for optical tweezing and optofluidic microsystems for biomedical applications. In such a manner is our optical design specialization focused on broader multi-disciplinary goals. To ensure continued future success, our interdisciplinary research activities are complemented by a variety of graduate and undergraduate degree programs. Young students taking the engineering Bachelor programs at TU Ilmenau (e.g. Optronics, Mechatronics, Electrical and Mechanical Engineering, Technical Physics) are exposed to interdisciplinary projects through a broad course selection. Challenges in optical engineering and microsystems are addressed in subsequent Master (e.g. Master of “Micro- and Nanotechnologies”) and PhD programs like the Graduate School on Optical Microsystems funded by the Thuringian “Ministerium für Bildung, Wissenschaft und Kunst.” Professor Dr. Stefan Sinzinger Technische Universität Ilmenau Institut für Mikro- und Nanotechnologien- Macro Nano® Fachgebiet Technische Optik Postfach 100565 D – 98684 Ilmenau Mail stefan.sinzinger@tu-ilmenau.de Web www.macronano.de RESULTS AND SERVICES FROM RESEARCH CLUSTERS AND INSTITUTIONS 67 Distinguished Services for Telecommunications For many decades now the Fraunhofer Heinrich Hertz Institute has been synonymous with outstanding achievements in the field of optical communication technology, and in future too we will continue to play a leading role in the development of high-end energy-efficient components for photonic networks, systems and components in association with our customers across the world. Optical communication technology can look back at a tradition spanning almost 50 years at the Fraunhofer Heinrich Hertz Institute (HHI). Work in this field at HHI began immediately following the discovery by the 2009 Nobel Prize laureate Charles Kuen Kao that ultrashort light pulses can be sent simultaneously over long distances through very thin glass cables without any significant loss of data. With on-going support from the Federal Ministry of Research, a raft of expertise was thus built up which nurtured a whole series of outstanding achievements. Even though a first impression might arise that each new record is only relevant to the scientific research community, history teaches us that such records are a means of highlighting the applicability of new developments to the worldwide communications infrastructure. Records are the driving force for overcoming – physical – boundaries! Without such outstanding achievements there would be no Internet today! The selection of HHI records below will give you a general impression. • 2.24 Gbit/s transmission system (1980) • 2.56 Tb/s over 160 km DQPSK (2005) • 160 Gb/s transmission over 4,000 km (2006) • 107 Gb/s transmission with integrated ETDM-receiver (2006) • 160 Gb/s unrepeatered transmission over 293 km (2007) • 5.1 Tb/s data generation and reception (2009) • 500 Mb/s over a standard LED light Gesture steering Source: Karl Storz GmbH Co KG A great number of developments have been realized working in close collaboration with our industry partners – companies such as Alcatel Lucent, Fujitsu, Micram, Nokia Siemens Networks, Siemens, ADVA , TESAT and Xtera, to name but a few. Photonic components from the Fraunhofer Heinrich Hertz Institute are now integrated in telecommunications systems across the world such as the XTERA transatlantic route or TESAT 5.5 Gb/s satellite-to-satellite communication. One regional alliance gave birth to the Berlin Access project which builds a FTTH (fiber to the home) transceiver which connects buildings and apartments to the optic fiber infrastructure. With u2t Photonics GmbH, an spin-off of HHI has become the world market leader in ultra-rapid (up to 100 Gbit/s) detectors and receivers. Statistically speaking, every second telephone call is made via components from this company. And since Cogo Electronics GmbH set up in Berlin, we now have a partner with whom we can work together in developing the most powerful and energy efficient transmitter for the world market. In Berlin we are fortunate to enjoy a most privileged situation. OptecBB is a strong proactive network that brings together companies and institutes in the region. Other hard locational factors – like a well qualified, highly skilled workforce – make the Berlin-Brandenburg region along with Silicon Valley one of the most attractive places for photonic communication technology. The Heinrich Hertz Institute will play its part in continuing to ensure that this remains so in future as well. Prof. Dr.-Ing. Hans-Joachim Grallert Executive Director Fraunhofer Heinrich Hertz Institute Einsteinufer 37 D – 10587 Berlin Phone +49(0) 30 - 31002 - 200 Mail hans-joachim.grallert@hhi.fraunhofer.de 3DTV sharp ® Ansgar Pudenz/alphadog RESULTS AND SERVICES FROM RESEARCH CLUSTERS AND INSTITUTIONS 68 Fraunhofer IWS Short profile The Fraunhofer IWS Dresden carries out application-oriented research in the fields of laser and surface technology. In the area of laser technology, the IWS focuses on material-oriented laser materials processing and the development of laser-specific system solutions. The goal here is to develop innovative technologies for industrial customers and to support them during technology transfer. The surface and coating technologies primarily address wear and corrosion protection, functional coatings as well as the ablation, structuring and repair of surfaces. Fiber Lasers Quietly Revolutionize The World For more than 50 years lasers have been successfully established in research and industry. Now, a special configuration is taking the fast lane: the fiber laser. Its advantages are obvious: due to the fiber design the beam quality is close to perfect, hence best possible focus ability even with very long operating distances is ensured. Flexible fiber geometry and vibration insensitivity as well as high efficiency and low operating costs convincingly allow an uncomplicated integration in industrial, automated production processes. A diversified consortium on the European level works together to set new standards in the field of fiber laser technology. Main objective of the EU-project LIFT (Leadership in Fibre laser Technologies) which started in September 2009 is the offensive consolidation of Europe's scientific, engineering and production-related leadership position. Coming from 9 different countries, expertise of 15 decisive companies, among them two Fraunhofer institutes, three universities and one non-profit organization joined and constitute a strong consortium. Managed by the Fraunhofer IWS Dresden, laser suppliers, producers of optical and opto-electronic components, manufacturers of photonic fibers and fundamental re- Fig. 1: Welding with fiber laser Fig. 2: Remote cutting with fiber laser searchers as well as application engineers are working on several goals. The consortium focuses on the development of fiber-based short pulse lasers for so called gentle "cold treatment" of materials, in particular for special ceramicmaterials, being of increasing interest in various areas. Another key role plays the progression of ultra reliable, pulsed high-performance- fiber laser systems which will significantly enhance processes like remote-laser cutting or welding in their efficiency. A specific challenge within the medical sector will be the realization of a three-color fiber laser. The aim is to develop a narrowband fibre laser system which is continuously emitting VIS radiation at wavelengths specifically chosen to treat various symptoms like acne or retina indisposing. Furthermore, this laser system will permit to combat certain types of cancer via photodynamic therapy. Additionally, the project addresses the sector of renewable energies. As the technical efficiency of photoelectric cells reaches its upper limit, the consortium will focus on the improvement of individual production steps in the manufacturing of solar modules. Pulsed high performance fiber-laser systems in combination with intelligent remotebeam delivery components will allow the up to now very intricate large area processing of solar substrates. Almost unnoticed by the end user, the fiber laser proceeds on its way to a crucial component of Europe's high technology and so quietly revolutionizes the production and medical technology of tomorrow. Fraunhofer Institute for Material and Beam Technology IWS Dresden Dr. Udo Klotzbach Winterbergstraße 28 D – 01277 Dresden Phone +49(0) 351 - 83391 - 3252 Mail udo.klotzbach@iws.fraunhofer.de Web www.lift-project.eu RESULTS AND SERVICES FROM RESEARCH CLUSTERS AND INSTITUTIONS 69 Mirrors for X-Rays and EUV Radiation Motivation and Applications Due to its much shorter wavelength as compared to visible light, the technical and commercial impact of extreme ultraviolet (EUV) and X-ray radiation steadily increases. One of the currently most important applications of mirrors for this spectral range is the EUV lithography, the emerging outstanding high precision requirements. X-ray mirrors consist of many hundred or several thousand single layers with thicknesses in the range of 0.5 – 20 nm. This combination of nanotechnology and optics requires specific knowledge and can only be successfully managed with tailored coating equipment. In order to fabricate the coatings with high precision and reproducibility, the Fraunhofer IWS Dresden has established various complementary technologies like magnetron and ion beam sputter deposition (MSD and IBSD). The corresponding upscaling of the technologies has been carried out in several projects together with Roth & Rau MicroSystems GmbH. Currently, substrates with dimensions of up to 500 mm (IBSD) and 680 mm (MSD) can be coated with outstanding uniformities and reproducibilities. For typical nanometer multilayers precision and reproducibility requirements in the picometer range have to be fulfilled (1 pm = 0.000000000001 m)! Using the newly developed coating machine MS 2000 (fig. 3) these specifications can be met on large-scale mirrors. Fig. 1: Scheme of the EUV lithography technology for the fabrication of integrated circuits (fig. 1). Corresponding to Moores law, in a few months semiconductor structures with dimensions < 22 nm have to be printed. From today’s point of view EUV lithography will be the only cost-effective technology for high volume manufacturing. Beyond EUV lithography, the use of X-ray and EUV mirrors has been already well-established in synchrotron beamlines (fig. 2), X-ray diffractometers/reflectometers and in fluorescence analysis instruments. Technological background The utilization of EUV radiation and X-rays has forced the development of completely new reflection coatings with Fig. 2: Synchrotron mirror with tailored reflection coatings Fig. 3: Coating machine MicroSys 2000 for mirrors with diameters of up to 680 mm Fraunhofer Institute for Material and Beam Technology IWS Dresden Dr. Stefan Braun Winterbergstraße 28 D – 01277 Dresden Phone +49(0) 351 - 83391 - 3432 Mail stefan.braun@iws.fraunhofer.de Web www.iws.fraunhofer.de/technologien/x-ray-optics Roth & Rau MicroSystems GmbH Dr. Michael Zeuner Gewerbering 3 D – 09337 Hohenstein-Ernstthal Phone +49(0) 3723 - 498833 Mail michael.zeuner@roth-rau.de Web www.roth-rau.de RESULTS AND SERVICES FROM RESEARCH CLUSTERS AND INSTITUTIONS 70 The Network – PhotonikBB Aims of the network Laser Technology Photovoltaics Photonic Components Measurement and Sensor Technology PhotonikBB is a network of partners from science and industry, created to implement scientific research results in the field of photonics in commercial applications. It strengthens the cooperation between companies, universities and institutes. So today, tomorrow’s innovations are being developed and produced at the Berlin Brandenburg location. For this, the network initiates, coordinates and promotes the merging of competences in joint projects. For this purpose, PhotonikBB will build up interdisciplinary cooperation projects between industry and the most various scientific institutes. Particular importance is attached to bring small and medium sized creative companies into cooperation with science, thus forming top clusters with a high degree of competence and a strong industrial connection and to occupy future and key markets. The branch competence field of optical technologies hence strengthens the economic development of the entire region Brandenburg/ Berlin and creates new and top-quality jobs. As an innovation driver for other application-oriented branches, PhotonikBB permanently improves the competitive capability of local industry and users e.g. in material processing and sensors with powerful and innovative solutions from Photonics. PhotonikBB is an association of companies and scientific institutions in an interdisciplinary photonic cluster along the value chains. The association permanently ensures network cooperation, for example by creating a central provider database for products, services and project ideas and the formation of a pool of experts. Cooperation in the network • Supporting industry, strengthening research and development • Representing the interests and optimising the cooperation of the partners • Interlocking of industry and science • Training and securing of skilled labour • International, cross-border cooperation of companies and scientific institutions • International image as the photonic region Brandenburg-Berlin • Intensification and enlargement of innovative force • Creation of the brand »Photonics made in Brandenburg-Berlin« • Added value of the optical technologies in Brandenburg and Berlin Focal points of the activity • Lobbying and initiation of knowledge and technology transfer between industry and science in close cooperation and using the offer of the ZAB, of Berlin Partner and of the TSB Adlershof • Formation of a pool of experts whose tasks include the assessment of projects and the participation in network events • Creation and establishment of a permanent communication platform • Support in the creation of horizontal and vertical network structures PhotonikBB e.V. Potsdamer Str. 18a D – 14513 Teltow Phone +49(0) 3328 - 430 - 230 Fax +49(0) 3328 - 430 - 230 Mail Mail@photonik-bb.de Web www.photonik-bb.de RESULTS AND SERVICES FROM RESEARCH CLUSTERS AND INSTITUTIONS 71 Functional Materials – The Applications becoming more and more multifaceted! The Fraunhofer IAP develops customer specific applications for organic light emitting diodes (OLEDs), organic photovoltaics (OPV), organic electronics and sensors. OLEDs provide a larger angle of view, give off a brighter image and are printable. Combining OLEDs with organic electronic components or with other functional elements such as foil keyboards enables completely flexible applications to be built. Materials for organic electronic devices The development of these elements based on organic electronics requires materials with predictable and reproducible performance. Organic chemistry opens a wide spectrum of possibilities for tailor-made materials. For OLEDs new phosphorescent polymers were designed by the integration of structure optimized and energy level adapted hole-, electron transport and phosphorescent molecules as side- groups to one polymer backbone. By using additional reactive monomers, the new polymer materials can be crosslinked by thermal or photochemical initiation to stabilize deposited thin films in subsequent process steps. Technology for organic electronic devices The goal of the work is to develop intelligent systems in the application areas of life science, textiles and architecture which combine OLEDs, OPV, polymer electronics, sensors and energy storage. Research and development will focus on utilizing deposition technologies in inert and non-inert conditions which are solution based. These new applications require completely new technological steps, including development of the layout of the display or illuminated area, the architecture of the series of deposits and the effective encapsulation of the components. The most important aspects that still have to be addressed are the efficiencies of the devices and their operating lifetimes. Optical functional elements Optical functional elements for LCDs, such as polarizers, color filters, diffusers, retarders and aligning layers are being developed with the aid of anisotropic optical functional layers. Polymer materials with photosensitive properties are required as optical functional layers in LCDs. The specially functionalized polymers, polymer composites and photocrosslinkable liquid crystal mixtures can be readily processed enabling films to be prepared with different optical functionalities. In addition to materials development, technological steps include film and device preparation through spin-coating, printing techniques, anisotropic orientation of the films, permanently fixing the orientation in the glass state and/or photocrosslinking. New thermotropic liquid crystals are being developed for anisotropically structured, ultra-thin films with complex optical properties. The core of this work involves developing efficient, multistage synthesis sequences and analyzing liquid crystalline properties. Fraunhofer-Institut für Angewandte Polymerforschung Geiselbergstraße 69 D – 14476 Potsdam Phone +49(0) 331 - 568 - 1910 Mail info@iap.fraunhofer.de Web www.iap.fraunhofer.de www.oled-research.com Innovations and Competencies in Industry INNOVATIONS AND COMPETENCIES IN INDUSTRY 74 Field Tracing by VirtualLab™ for System Analysis and Design Field tracing generalizes the concepts of ray tracing: harmonic fields are traced through the system instead of ray bundles. Hence field tracing utilizes and provides more information about the light in optical systems. Field tracing enables unified optical modeling that integrates simulation techniques ranging from geometrical optics to electromagnetic methods. Based on these technologies VirtualLab™ offers an unsurpassed flexibility and efficiency in optical modeling. The toolboxes of VirtualLab™ allow the investigation of nano- and micro-optics, diffractive optics, laser systems, ultra-short pulses, laser resonators, LEDs, excimer lasers, gratings, photonic crystals, artificial materials and much more. All toolboxes work fluently together on a single platform. Features VirtualLab™ addresses a wide range of modeling tasks arising in the design and analysis of optical systems: • Modeling of lenses, free-form as well as micro and diffractive optical components. • Diffraction, interference, aberrations, polarization, vectorial effects, temporal and spatial partially coherence are taken into account. • Optimization of diffractive diffusers, diffractive homogenizers, diffractive beam splitters, diffractive and refractive beam shapers. • Electromagnetic analysis and optimization of 2D and 3D surface and volume gratings. • Analysis of laser cavities including computation of fundamental and higher modes. • Modeling of a great variety of light sources including multi-mode lasers, excimer lasers and LEDs. Methods Unified optical modeling allows the combination of different propagation techniques in order to reach a required accuracy with optimal effort. The following methods are available: • Rigorous and approximate free space propagation methods including spectrum of plane waves, Fresnel and far field integral. • Geometrical optics propagation methods considering also vectorial effects as required for high NA systems. • Split step beam propagation methods for inhomogeneous media. • Rigorous Fourier modal method (FMM) for periodic 2D and 3D gratings. Applications VirtualLab™ can be applied in many fields of applications to analyze optical systems including tolerance analysis and parameter variation: • High-NA laser, laser optics, imaging systems and laser material processing. • Photovoltaic systems, photonic crystals, sensor technology and microlithography. • Illumination and display systems. • Ultra short pulses. • Laser resonators. LightTrans GmbH Wildenbruchstraße 15 D – 07745 Jena Phone +49(0) 3641 - 664353 Fax +49(0) 3641 - 664354 Mail info@lighttrans.com Web www.lighttrans.com LASER, OPTICS: DESIGN 75 JCMwave: Complete Finite Element Technology for Optical Simulations Accurate simulation of light propagation is indispensable in nano-technologies JCMwave transfers state-of-the-art numerical methods to innovative software products for cutting-edge applications. JCMwave offers a complete simulation suite for a broad range of applications in nano-optics. These include integrated optical components, textured solar cells for photovoltaics, metamaterials, photonic crystal fibers, nearfieldmicroscopy, semiconductor lasers, and optical microlithography. JCMwave's products rely on fundamental concepts in mathematics and computer science. This results in exceptionally short computation times, compact data space requirements and highly robust software. sive set of postprocessing tools tailored to engineering needs. A CAD tool for the construction of realistic 2D and 3D geometries completes the tool box. JCMwave's main product, the finite element package JCMsuite, comprises powerful finite element technologies for the computation of electromagnetic waves. The finite element method is considered the method of choice for accurate and fast simulations of light interaction with nanostructures. The superior performance of JCMsuite has been pointed out in several benchmarks. Main ingredients for the outstanding performance are adaptive mesh refinement, higher-order vector elements, fast numerical methods for solving matrix equations, and a comprehen- JCMsuite is also well suited for pattern reconstruction in optical metrology. Optical inspection in a productive environment requires very short computation times for high throughput. When complex patterns are involved this can be an extremely demanding numerical task. We offer two innovative solutions: First, a new rigorous scheme allows obtaining results even in real-time applications. Second, parallelized domain-decomposition approaches enable accurate solutions on very large computational domains. JCMwave’s team of engineers, physicists, and mathematicians supports its partners in performing goal-oriented design, analysis and optimization of optical components. JCMwave GmbH Bolivarallee 22 D – 14050 Berlin Phone +49(0) 30 - 84185 - 480 Fax +49(0) 89 - 2555 - 132 - 369 Mail info@jcmwave.com Web www.jcmwave.com INNOVATIONS AND COMPETENCIES IN INDUSTRY 76 Successful Solutions – with Cutting Edge Technologies At LIMOs headquarters in Dortmund, Germany, an international team of 200 engineers, physicists, technicians and many other specialized staff develops, manufactures and sells innovative micro optics and laser systems. We regard ourselves as strategic partner to leading companies using laser photons. Our mission is to make business partners in the material processing & photonic industries more successful with cutting edge technologies. Micro optics & optical systems We develop and produce wafer-based optical components and systems, suitable for cost-effective mass production of premium lenses and customized beam shaping solutions. These systems guarantee uniformity up to 99%. Our patented manufacturing process uses only high-quality glass and crystals for a long lifetime. We are world-market leader in refractive micro optics and have been awarded for this technology with the “world’s first innovation award”. (Innovationspreis der deutschen Wirtschaft 2007) We offer as well complete optical systems for the following industries. • flat panel displays • micro lithography • photonics (beam shaping for all high power laser systems) • photovoltaics High power diode lasers, laser complete systems & laser workstations LIMOs diode lasers impress with highest brightness and a robust industrial design. All high-efficient and long-lasting laser modules are also available as complete systems for any application. Our in-house produced refractive micro optics ensure high efficiency for customized beam shaping. That guarantees lower failure rates, lower electricity consumption, reduced cooling requirements and a longer life time. Our laser system technology products are used in industries like: • medical technologies • photonics (pumping) • automotive • flat panel displays • photovoltaics Technical service & consulting Altogether we offer full service in every way: Whether you need customized assembly, installations-, maintenanceand repair-services or an engineering seminar, a feasibility study or methodical project management, LIMO is able to provide exactly what you require. For the various fields of applications for laser materials processing, we have installed an Applications Center that shows you the advantages of the LIMO technologies. The flexible design of the Applications Center also allows shortterm customer-specific technology testing and training on new systems. In this Applications Center, we demonstrate our solutions "live" in use in a suitable environment – from individual laser systems to complete materials processing systems. LIMO Lissotschenko Mikrooptik GmbH Bookenburgweg 4 – 8 D – 44319 Dortmund Phone +49(0) 231 - 22241 - 0 Fax +49(0) 231 - 22241 - 301 Mail kontakt@limo.de Web www.limo.de LASER, OPTICS: SYSTEMS 77 We think laser ... ... and we have been doing so for 35 years. With more than 38,000 installed systems worldwide, the ROFIN Group is one of the leading suppliers of lasers and laser-based system solutions in industrial materials processing. Lasers used for cutting, welding, marking, and surface treatment have become indispensable tools for a variety of today’s manufacturing processes. More than 1,800 qualified employees at about 35 locations worldwide guarantee a meaningful contribution to the laser technology of the future. ROFIN – Lasers provide solutions Processing materials with lasers offers a wide range of technical advantages. In many applications lasers allow stronger welds, faster cuts, finer structures and permanent durable marks. A team of application specialists are available worldwide to provide an appropriate laser solution or to develop new applications. Cooperation with laser institutes ensure that ROFIN is always up to date in all important areas of applications. With CO2, fiber lasers, solid-state lasers, diode lasers, and various Q-switched lasers, ROFIN offers one of the broadest and most powerful product range in industrial materials processing today. M3 – Macro, Micro, Marking The company is structured around three core areas of competence, Macro, Micro and Marking. With the emphasis on these three core operations, ROFIN is able to react quickly and efficiently to the customers’ needs and find optimum solutions for individual requirements. ROFIN Macro offers a wide range of CO2 lasers from lowpowered sealed-off products to multi-kilowatt lasers. The low-maintenance, diffusion-cooled CO2 Slab lasers leads the mult-kilowatt range. This product is integrated into cutting lines & welding systems all over the world. The new fiber lasers are used for application fields that require flexible beam guidance with fiber optics. Diode-pumped lasers in rod or disc design or as Q-switched lasers complement the solid-state laser solutions. The product portfolio is rounded off by compact and maintenance-free high power diode lasers for heat conduction welding, surface hardening and brazing. ROFIN Micro offers a broad range of laser sources such as ultrashort pulse laser for the “cold” cut and ablation. The product portfolio also includes system solutions for processing parts down to the μm-range. Even with the most sensitive materials, the highest precision and lowest heat affected zone is achieved. The business activities include industry proven laser beam sources with all required wavelengths and powers, compact and mobile all-in-one machines with manual or CNC control units and integrated solutions for entire automation. Supplemented with, for example, the quick scanner head technology and powerful CAD software control, market leading systems for micro material processing and innovative new laser solutions are created. The continuously increasing application area includes precision cutting and welding, micro drilling, structuring, perforating and plastics welding. ROFIN Marking is one of the market leaders in the area of laser marking. The precise, fast, non-contact, permanent marking of almost all materials with lasers has found a place in vast areas of industrial manufacturing. Compact diode-pumped Nd:YAG and Nd:YVO4 laser systems with wavelengths of 1064 nm, 532 nm and 355 nm as well as fiber and CO2 lasers are used to mark an almost limitless variety of organic and inorganic materials. Manifold, ingenious technical options assure a wide range of possible applications offering different integration stages. ROFIN-SINAR Laser GmbH Berzeliusstrasse 87 D – 22113 Hamburg Phone +49(0) 40 - 73363 - 0 Fax +49(0) 40 - 73363 - 4100 Mail info@rofin-ham.de Web www.rofin.com INNOVATIONS AND COMPETENCIES IN INDUSTRY 78 Omicron-Laserage Laserprodukte GmbH Flexible Lasers and LED Light Sources for Industry and Science Omicron, located in Rodgau in the Rhein-Main area, develops and produces state-of-the-art diode lasers and DPSS lasers for the industry. Founded in 1989, Omicron is a well established company which has succeeded in positioning itself as a market leader in the area of laser diode systems and laser applications within a relatively short time-span. At first Omicron focused its production on opto-mechanics, laser optics and fibre couplers. In 1997 the company began, with increasing success, developing and producing lasers in-house. Since then, the team has continuously grown and meanwhile launches countless innovations and new products every year. Examples are the successful LDM-Series and the lasers of the FK-LA-Series which were developed for high-end laser applications such as Computer to Plate (CtP), DVD mastering, wafer inspection, microscopy and reprography. Continuing to develop products in order to remain a step ahead of current standards is an integral part of Omicron’s philosophy. One secret behind the success is the modular principle Omicron uses for construction. This is to great advantage for the customer since it allows an easy integration of both LDM- and FK-LA series lasers in existing and new machines, so that adjustments in accordance with customer’s wishes can be made at any given point in time. Further important developments were the PhoxX®compact high-performance laser in 2008, LuxX® compact CW diode lasers and SOLE®laser light engines in 2009 as well as the LightHUB®beam combiners in 2010. With these developments, Omicron is one of the leading manufacturers for demanding applications in biotechnology, microscopy, microlithography and many more. Innovative Products LuxX® Compact CW Diode Lasers With the LuxX diode laser series, Omicron is showing the way forward in the 375-830 nm wavelength range. The LuxX series offers many unbeatable advantages when compared with conventional argon gas and DPSS lasers. As a result of the fast, direct analogue power modulation of greater than 1.5 MHz, and a full ON/OFF shutter function of greater than 150 kHz, opto-acoustic modulation is no longer needed. Compact construction and flexible input signalling allows the lasers to be integrated simply into existing or future machine designs. One significant feature of the LuxX diode laser is its all integrate intelligent laser electronics with RS232 and USB 2.0 interfaces that permit easy interaction with the application. The ultra compact footprint of only 4 x 4 x 10 cm makes these lasers the most compact in the market. Furthermore, by using innovative Omicron optics, astigmatism is corrected so that the beam has a diameter of around 1mm and the focus is absolutely circular. The lasers are available in 14 different wavelengths between 375 and 830 nm with single-mode optical output powers up to 150mW. Multi Wavelength Solutions The SOLE® laser light engines and LightHUB® compact beam combiners represent a new era of Omicron products. Especially designed to meet today´s needs in biotech and microscopic applications, they combine up to 6 wavelengths of diode and DPSS lasers. The SOLE® light engines are compact laser sources with up to six lasers, coupled in up to two single mode fibers. The SOLE® systems offer fast analogue and digital modulation for each laser line and fast switching between the individual wavelengths. The LightHUB®compact beam combiners are able to steadily combine the laser beams of up to four diode or DPSS lasers into a co-linear beam, which can then be used in free-space or fiber coupled applications. Where the SOLE® laser light engines mainly address end-users, the LightHUB® compact beam combiners are very attractive for OEM integration. For both products, the customer can choose from over 20 different wavelengths in the range of 375 to 830nm. Various power levels of up to 200mW per laser line are available. Omicron-Laserage Laserprodukte GmbH Raiffeisenstr. 5e D – 63110 Rodgau Phone +49 (0)6106 - 8224 - 0 Fax +49 (0)6106 - 8224 - 10 Mail mail@omicron-laser.de Web www.omicron-laser.de LASER, OPTICS: SYSTEMS 79 TOPTICA Photonics AG: Diode and Fiber Lasers for Industry and Research Over the last years, TOPTICA Photonics has become one of the leading laser photonics companies in Europe. Based near Munich, Germany, TOPTICA develops and manufactures high-end lasers and laser systems for scientific and industrial applications in the three following technology fields: diode and fiber lasers as well as Terahertz system design. Among our customers are not only high-tech companies in the life sciences, the semiconductor industry or quality assurance but also nearly a dozen Nobel Laureates. In den letzten Jahren hat sich TOPTICA Photonics zu einem führenden Unternehmen im Bereich Laserphotonik in Europa entwickelt. Am Firmensitz in München konzipiert und fertigt TOPTICA Laser und Lasersysteme für den Einsatz in Forschung und Industrie in den drei Technologiefeldern Diodenlaser, Faserlaser und Terahertz-Systemdesign. Unter unseren Kunden befinden sich HighTech-Firmen aus den Bereichen Life Sciences, Halbleiterindustrie und Qualitätssicherung sowie ein dutzend Nobelpreisträger. About 100 highly skilled employees transfer today’s research technology into new products for industrial applications. Latest research and customer needs are closely linked in order to meet the requirements for leading-edge solutions. Scientific and OEM customers alike appreciate the sophisticated performance of our systems as well as long lifetime, high reliability and stability. A subsidiary in Rochester, NY, USA and a worldwide distribution network ensure best service and short response-times for our international customers. Ein wesentlicher Punkt der Firmenphilosophie ist die enge Verzahnung von Kundenbedürfnissen und aktueller Forschung bei der Entwicklung innovativer Produkte. In unseren Laboren setzen etwa 100 hochqualifizierte Mitarbeiter Forschungsergebnisse von heute in Produkte von morgen um und bringen diese zur Marktreife. Industrie- und wissenschaftliche Kunden schätzen die Leistungsfähigkeit und Langlebigkeit unserer Systeme sowie ihre hohe Zuverlässigkeit und Stabilität. Durch die Außenstelle in Rochester, NY, USA und ein weltweites Netzwerk von Distributoren gewährleisten wir unseren internationalen Kunden umfassenden Service und schnelle Reaktionszeiten. Latest development at TOPTICA TOPTICA has significantly expanded its offering of ultrashort pulsed fiber laser technology over the last years. The activities have specifically focused on metrology and biophotonics solutions, a development that will continue in the next couple of years. TOPTICA Photonics AG Lochhamer Schlag 19 D – 82166 Gräfelfing Phone +49(0) 89 - 85837 - 0 Fax +49(0) 89 - 85837 - 200 Mail sales@toptica.com Web www.toptica.com Letzte Neuerung bei TOPTICA Über die letzten Jahre hat TOPTICA das Angebot an Ultrakurzpuls-Faserlaserlasern erheblich ausgebaut. Ein besonderer Schwerpunkt liegt dabei auf Lösungen für die Messtechnik und die Biophotonik; Bereiche, die in Zukunft weiter ausgebaut werden sollen. INNOVATIONS AND COMPETENCIES IN INDUSTRY 80 Northrop Grumman LITEF GmbH Solutions for a World in Motion NG LITEF GmbH offers optical phase- and amplitude modulators with GHz bandwidths NG LITEF GmbH hat mehr als 20 Jahre Erfahrung in der Herstellung optischer Modulatoren. Northrop Grumman LITEF GmbH (NG LITEF) designs, develops and manufactures motion sensors and systems for navigation solutions and industrial applications. From its base in Freiburg, southern Germany, NG LITEF successfully sells its products worldwide. NG LITEF’s products use key technologies including fiber optics, integrated optical circuits, MEMS, electronics, software and miniaturised packages and assemblies. NG LITEF is a company fully certified according to DIN ISO 9001. Our company is committed to continual development and product improvement with leading technologies. Our focus is innovation in the market and providing sensor and system solutions for our customers. For example, NG LITEF’s optical phase modulators, based on a lithium niobate substrate, are used in pure closed-loop Sagnac interferometers, and provide high precision measurement of rotation. The devices are developed and manufactured in house and are extensively tested before delivery. More than 120,000 of these devices have been produced to date and are in worldwide use in, for example, flight-critical applications. Thanks to continual enhancement, our optical modulators, with both phase and amplitude modulation, are available in series production with space proving. They offer reliable data transmission in the range of GHz bandwidths at the standard 1064 nm of satellite optical communication applications. Northrop Grumman LITEF GmbH Loerracher Strasse 18 D – 79115 Freiburg Phone +49(0) 761 - 4901 - 0 Mail info@ng-litef.de Web www.northropgrumman.litef.de Northrop Grumman LITEF GmbH (NG LITEF), zuhause in Freiburg im Breisgau, entwickelt, produziert und vertreibt weltweit Sensoren und Systeme für Navigationslösungen und industrielle Anwendungen zur hochgenauen Messung von Drehbewegungen und Beschleunigungen. Hierzu werden Kerntechnologien wie Faseroptik, integrierte Optik, MEMS, Elektronik, Software und entsprechende Aufbau- und Verbindungstechniken genutzt. NG LITEF ist in allen Funktionsbereichen nach DIN ISO 9001 zertifiziert. Unsere Firmenphilosophie ist auf die konsequente Weiterentwicklung von Hochtechnologien im Sinne der Marktbedürfnisse innovativer und kundenangepasster Sensor- und Systemlösungen ausgerichtet. Für den Einsatz der optischen closed-loop Sagnac-Interferometer zur hochpräzisen Messung von Drehraten werden beispielsweise integriert-optische Phasenmodulatoren in Lithium-Niobat Technologie selbständig im Hause entwickelt, in Reinräumen gefertigt und vor Auslieferung ausgiebig getestet und vermessen. Mehr als 120.000 solcher Modulatoren wurden bereits hergestellt und sind weltweit u. a. in flugkritischen Anwendungen erfolgreich im Einsatz. In den letzten Jahren ist es uns gelungen, die optischen Modulatoren konsequent weiter zu entwickeln. Heute sind bei NG LITEF weltraumgetestete Phasen- als auch Amplitudenmodulatoren in Serie verfügbar, die im Bereich der optischen Satellitenkommunikation bei 1064 nm zuverlässige Datenübertragungsraten mit GHz-Bandbreiten erlauben. Wenn Sie mehr erfahren möchten, wenden Sie sich bitte an die angegebene Kontaktadresse, gerne informieren wir Sie über unsere Produkte und Dienstleistungen. LASER, OPTICS: SYSTEMS 81 Your OEM partner for Laser Systems and Subsystems LASOS is a leading manufacturer of laser products for OEM equipment, particularly in the biophotonics, instrumentation and measurement technology, with a special focus on the customer specific production of laser modules and subsystems and the development and production of application-related system solutions. LASOS serves many globally reputable manufacturers with stringent demands on reliability and durability, and has become the world’s leading OEM supplier for confocal microscopy. LASOS develops and manufacturers lasers for the visible and near-ultraviolet/infrared spectrum in particular, with outputs of up to several hundred mW. The product range encompasses gas laser technology, diode lasers and diodepumped solid-state lasers. The LASOS LasNova series diode laser modules and diode-pumped solid-state lasers are built into compact, robust and energy-efficient equipment. The single-frequency operation of diode pumped solid-state lasers facilitates their use in many fields of biophotonics and also Raman spectroscopy. The Ar-ion laser with its outstanding price-performance ratio is still the workhorse for multiwavelength applications in particular, such as in fluorescence stimulation. Durable He-Ne lasers, too, with their excellent beam properties, are still very much the standard for many applications. Fiber coupling is a viable option where greater flexibility and modular design are key. The solution guarantees a permanently stable, adjustment-free fiber connection and can be equipped with customer-specific mechanical-optical interfaces. The majority of LASOS manufactured products are customer-specific, although the company also provides a standard product range. Tailored solutions designed to address specific customer requirements or for a predetermined application facilitate the development of integrated solutions that save time and money. With a tightly knit development, construction and manufacturing chain, LASOS is able to contribute specialist knowledge to customer projects early on, assisting the definition of mechanical and optical interfaces that ensure the practical feasibility of the solutions. The quality and longevity of LASOS products are of primary concern throughout the manufacturing process. Accordingly, every stage from the goods receipt inspection to the final inspection is organized and checked in accordance with our quality management specifications. ISO 9001 certification and regular manufacturing facility audits by TÜV ensure that high quality is maintained in development, manufacturing and project processing, thus guaranteeing the reliability, consistency and sustainability of LASOS products. Products and services at a glance • Diode pumped solid state lasers 473, 532, 540, 56 nm; Up to 100 mW, single frequency • Diode laser modules 405 … 488 nm, 635 … 830 nm; Up to 100 mW, free beam or fiber coupled • He-Ne lasers, 633, 543, 594 nm up to 18 mW • Ar-ion laser, 458 … 514 nm up to 40 mW • Customized optical subsystems, beam combiners, housings • Fiber coupling option for all laser models LASOS Lasertechnik GmbH Carl-Zeiss-Promenade 10 D – 07745 Jena Phone +49(0) 3641 - 29 44 - 54 Mail lasosinfo@lasos.com Web www.lasos.com INNOVATIONS AND COMPETENCIES IN INDUSTRY 82 HighFinesse GmbH – Ultimate wavelength measurement HighFinesse GmbH, located in Tübingen, is celebrating its 10th anniversary this year as a worldwide leading supplier of wavelength measurement devices. Since it was founded in 2000, HighFinesse specializes in a range of different products for research, science, industry and medical applications and is particularly known for the WS series of wavelength measurement devices. With accuracy down below 2 MHz the WS Ultimate-2 is to date the most accurate commercially available technology for measuring pulsed and continuous wave lasers. Because of the Fizeau technology with no moving parts, HighFinesse wavelength meters are very robust and allow high-speed measurements. Feedback control of up to eight lasers is possible as well. line width resolution of δλ/λ = 2*10-5. The new HDSA is able to analyze the whole spectrum of a light source at the same time. The resolution is λ/Δλ = 15000 over the whole spectrum from 400nm up to 900nm. NEW: Pulsed IR measurements at 2 to 12µm The current research focus at HighFinesse aims at closing the gap for pulsed IR applications. In 2011 a new IR wavelength meter will be presented for 2 up to 12 μm. The WS Ultimate-2 is to date the most accurate commercially available wavelength meter. The diagram confirms the absolute accuracy and long-term stability of the instrument. HighFinesse ensures a high-level quality management certified according to EN ISO 9001. Our products provide long lifetime, high reliability and flexible design customization to specific application requirements. Customers can rely on a global distribution network (see homepage) and enjoy worldwide technical support. "Customer orientation and customized solutions at the edge of technology are part of the reason why HighFinesse stays at the top of the worldwide competition," summarizes Dr. Thomas Fischer, CEO and founder of HighFinesse GmbH. NEW: High Definition Spectrum Analyzer (HDSA) In order to analyze the multi-line or broadband spectrum of light sources HighFinesse offers the Laser Spectrum Analyzer (LSA) and the High Definition Spectrum Analyzer (HDSA). Both work with an accuracy of 3 GHz. The LSA shares the advantage of high-speed measurement capability with our wavelength meters and achieves a minimum NEW: Stabilized Laser References (Highlight) The new Highlight-Series is the most recent addition to our product lineup. They are highly precise, fiber-coupled and self-(re)calibrating reference lasers. Product release is 2011, with the following wavelengths: Rb (780 nm), Cs (895 nm), C2H2 (1532 nm) and H2O (2000 nm). Featuring an absolute accuracy below 2 MHz and an output power of > 5 mW the Highlight-Series is beside other uses optimally fitted as calibration and reference source for any kind of wavelength meter. Precision Current Sources For physical and chemical precision applications HighFinesse offers high precision current sources. These ultrastable currents with extremely low-noise are most helpful for the use with "ultimate" magnetic field control, research and development at the quantum limit. HighFinesse GmbH Auf der Morgenstelle 14 D D – 72076 Tübingen Phone +49(0) 7071 - 96 85 15 Fax +49(0) 7071 - 96 85 17 Mail info@highfinesse.com Web www.highfinesse.com LASER, OPTICS: SYSTEMS 83 New Product Highlights: 500mW @ 670nm, 2500mW @ 780nm Sacher Lasertechnik offers a MOPA-System in the wavelength range of 670 nm to 1080 nm with output power of up to 2500 mW with high quality characteristics. State-ofthe-art computer interfaces, such as GPIB, USB and RS232 allow for easy handling and read-out of data. High power tunable single mode external cavity diode lasers with output power of up to 2500mW Optical cooling and trapping, • Rubidium, Cesium, etc. • Bose Einstein Condensation (BEC) • Cavity ring down spectroscopy (CRDS) Tunable external cavity diode lasers in Littman/ Metcalf configuration • Interferometry • Holography • Molecule spectroscopy • Cavity ring down spectroscopy (CRDS) Tunable external cavity diode lasers in Littrow configuration • Absorption spectroscopy • Optical cooling and trapping, Rubidium, Cesium, Indium, etc. • Bose Einstein condensation (BEC) • Raman Spectroscopy, in-vivo detection of glucose with diabetes patients Class D Antireflection coated diode lasers • Antireflection coated diode lasers with a reflectivity below 5E-5 for OEM and industrial customers • Plasma assisted deposition technology • Laser chip and laser bar handling technology Diode lasers • Fabry Perot Diode Lasers, FP • Distributed Feedback Diode Lasers, DFB • Distributed Bragg Reflector Diode Lasers, DBR • Broad Area Diode Lasers, BAL • Tapered Diode Lasers, TPL Pulsed Diode Lasers • 5 ns … 100 ns pulsed diode lasers Low noise diode laser controllers • 500mA operation current (<1 μA RMS, noise) • 4000mA operation current (<5 μA RMS, noise) Corporate Information: Sacher Lasertechnik is a well established business with more than 15 years experience in laser technology. The founder, Dr. Joachim R. Sacher is one of the pioneers of diode lasers with external cavity. The company has developed from a university spin-off to a technology leader in the field of high power tunable external cavity diode lasers. Sacher Lasertechnik U.S. was founded in 1999 for better serving U.S. customers. Intellectual Property: Dr. Joachim Sacher was one of the first scientists who recognized the commercial potential of external cavity lasers in connection with antireflection coated diode lasers. The first successful antireflection coatings were realized as early as 1987 at Marburg University. External cavity designs followed within the next years. Key elements of the technology basis are protected by several patent families. Due to these excellent proprietary solutions, Sacher Lasertechnik has become one of the fastest growing laser businesses worldwide. The Team: Sacher Lasertechnik is operated by an interdisciplinary research team consisting of physicists, electrical engineers, biologists – all with magna cum laude PhD or Diploma degrees. Research results are frequently presented at international conferences and published in leading industry magazines and science journals since 1989, c/f our publication summary. Up to now, Dr. Sacher has authored or co-authored a large number of articles in the field of external cavity diode lasers and their application. Due to our interdisciplinary research team, we have been able to extend this knowledge base into environmental and life science. Technology references are presented at our website. Sacher Lasertechnik GmbH Rudolf Breitscheid Str. 1-5 D – 35037 Marburg Phone +49(0) 6421 - 305 - 0 Fax +49(0) 6421 - 305 - 299 Mail jsacher@sacher.us Web www.sacher-laser.com INNOVATIONS AND COMPETENCIES IN INDUSTRY 84 Picosecond Lasers for Industrial Micromachining Thousands of lasers are manufactured every year for industrial laser processing. In these applications laser radiation - with pulses from millisecond to nanosecond range - is guided and focussed to a micron-size spot where the laser heats material and thereby melts and vaporizes it. Unfortunately, side-effects of these thermal processes cause micro-cracks, burrs and recast – that is, the edge material shows a heat-effect-zone that is acceptable in many applications, but undesirable or intolerable in many high quality micro-machining applications. It has been known for decades that ultra-short laser pulses can be used to avoid these side-effects and allow for higher quality. Until recently, the such lasers were complex, sensitive, expensive and bulky. LUMERA LASER was first to demonstrate an industrially packaged picosecond laser, the RAPID, and specializes in the development and manufacturing of ultrashort pulse lasers for industrial applications. Fig. 1: Example for ps-laser micromachining: Drilling Al, 100 µm diameter Fig. 2: Example for ps-laser micromachining: Drilling Si, 200 µm diameter high quality micromachining by “cold” ablation with good through put. One pulse ablates a layer up to 100 nm thick. With an 50 W laser, under good conditions, about 10 mm3 per minute of steel (6-60 mm3 for other materials) can be removed by ablation for a total cost of about 0.20 Euro/min. This rule of thumb allows checking whether a potential application can be done cost effectively and within permissible time constraints. LUMERA LASER`s application lab can demonstrate the principal effect on special materials and determine process parameters. Ps-Lasers can cut and drill any thin material in “cold” quality: to create highly defined apertures, electrodes, masks and test plates for the semiconductor or structure photovoltaic panels, stents, nozzles, filters, or only 10 nmdeep identification marks. More recently fast (400 characters/s) micromarking (5 μ line width) and fast (up to 1 m/s) separation of thin wafers, especially sapphire LED wafers, was reported. LUMERA LASER offers different models in the RAPID series with 6-50 W average power and pulse repetition rates of up to 1 MHz. In LUMERA LASER´s application lab high quality micromachining with picosecond lasers has been demonstrated on hundreds of materials. Generally an energy density of about 1J per cm2 is appropriate for Fig 3: Example for ps-laser micromachining: Drilling stainless steel, 35 µm diameter LUMERA LASER GmbH Opelstrasse 10 D – 67661 Kaiserslautern Phone +49(0) 6301 - 703 - 180 Fax +49(0) 6301 - 703 - 189 Mail info@LUMERA-LASER.com Web www.LUMERA-LASER.com LASER, OPTICS: COMPONENTS 85 Innovative Technologien für optische Komponenten Microsystems technology (MST) combines processes of micro electronics, micro optics and micro mechanics. Pick & Place, bonding and micro packaging are technologies for the production of microsystems. Innovative Technologies for optical Components The Micro-Hybrid Electronic GmbH develops and manufactures modern electronic and sensory components. Innovative development comprises new and further development of technologies, processes and components of micro systems technology and electronics. Goal of any development process is the solution of a customer task respectively a new product. The customer is integrated into every step of the development. Production of complex systems of Micro-Hybrid Electronic GmbH offers each customer an easy all-in-one solution. All project tasks are controlled and processed by us. In addition, the direct feedback from production offers new innovative approaches in development. By the wide range of technologies we are able to develop and produce innovative components and systems. For instance LEDs possible to autoclave for medicine technique, infrared detectors for gas monitoring and special components for analytical systems belong to our products. Particularly interesting is our ability to produce electronic and sensory components for operating temperatures up to 482°F. So many systems made at Micro-Hybrid Electronic GmbH are applicable on site and save complex telecontrol systems or expensive optics. Customers of Micro-Hybrid belong to market leaders in medicine, automotive, measurement systems and aerospace. The Micro-Hybrid Electronic GmbH is ISO 9001:2008 and TS16949:2009 certified. Micro-Hybrid Electronic GmbH Heinrich-Hertz-Straße 8 D – 07629 Hermsdorf Phone +49 (0)36601 - 592 - 100 Fax +49 (0)36601 - 592 - 110 Web www.micro-hybrid.de Die Micro-Hybrid Electronic GmbH entwickelt und produziert moderne elektronische und sensorische Komponenten. Die innovative Entwicklung umfasst die Neu- und Weiterentwicklung von Technologien, Verfahren und Komponenten der Mikrosystemtechnik, der Mikrooptik und der Elektronik. Das Ziel eines jeden Entwicklungsprozesses ist die Lösung einer Kundenaufgabe bzw. ein neues Produkt. Der Kunde wird in jeden Schritt der Entwicklung integriert. Die Fertigung komplexer Systeme unter dem Dach der Micro-Hybrid bietet dem Kunden eine umfassende All-in-OneLösung, alle sein Projekt betreffenden Aufgaben werden von der Micro-Hybrid gelenkt und bearbeitet. Zusätzlich bietet das direkte Feedback aus der Produktion neue innovative Ansätze in der Entwicklung. Durch die breite Palette anwendungsbereiter Technologien sind wir in der Lage, innovative Komponenten und Baugruppen zu entwickeln und zu produzieren. Dazu gehören beispielsweise autoklavierbare LEDs für die Medizintechnik, Infrarotdetektoren für die Gasanalyse und Spezialbauelemente für optische Analysesysteme. Besonders hervorzuheben sind unsere elektronischen und sensorischen Baugruppen, die für Betriebstemperaturen bis 250°C geeignet sind. Damit sind zahlreiche Systeme der Micro-Hybrid Electronic GmbH direkt vor Ort einsetzbar und sparen aufwändige Fernwirksysteme oder teure Optiken. Zu den Kunden der Micro-Hybrid Electronic GmbH gehören Marktführer aus den Bereichen Medizintechnik, Automotive, Messtechnik sowie Luft- und Raumfahrt. Die Micro-Hybrid Electronic GmbH ist nach ISO9001:2008 und TS16949:2009 zertifiziert. Our high sensitive multi channel thermopiles were developed especially for NDIR gas measuring systems with high precision. The thermopiles are qualified to measure one to three different gases by the use of special infrared filters. A reference channel guarantees that neither dust or smoke nor changes at the IR source have an influence on the measuring value. INNOVATIONS AND COMPETENCIES IN INDUSTRY 86 Qioptiq: Photonics for Innovation LINOS is now Qioptiq Through a series of acquisitions over the last several years, Qioptiq has an impressive history and pedigree. In particu- Machine vision, lasers, projection and more With more than 100 years of history and experience, Qioptiq is a trusted source for all of your machine vision, inspection and metrology products and solutions, from standardized high-end CCD lenses to customized premium solutions, for any purpose in the machine vision world. Our optics can also serve the specific needs of pre-press and projection applications. We also offer a full set of services and products for lasers, laser material processing, and laser-based machinery and related metrology and process-checking systems. We will serve you from development and prototyping to volume production. Precise, universal and reliable – the microbench system is widely used in research and industry Micro-optical components and systems for endoscopy and industrial applications lar, Qioptiq benefits from having integrated the knowledge and experience of LINOS AG. By unifying in this way, the company has strengthened its presence compared to its international competitors and allowed its customers better and smoother access to Qioptiq's comprehensive technical know-how and range of services. As part of this transformation, the world-famous LINOS Online Shop is now known as the Qioptiq-Shop. The change of name did not result in any other changes for LINOS customers and business partners; all contacts remain the same. Beyond these applications, companies also turn to Qioptiq for optical devices for production equipment, illumination and lighting, spectroscopy, imaging, civil security, assembly equipment, surveillance, optical recognition, food inspection, fabric and tissue production, security and construction, free space optical communication, space applications, and more. Qioptiq is your partner for any OEM needs. Qioptiq designs and manufactures photonic products and solutions that serve a wide range of markets and applications in the areas of industrial manufacturing, medical and life sciences, research and development, defense and aerospace. We are known for our high-quality standard components, systems and instruments, our custom modules and assemblies, our leading-edge innovation, our precision manufacturing and our responsive global sourcing. Qioptiq in Germany Today, 720 dedicated professionals work for Qioptiq at our sites in Asslar, Feldkirchen (Munich), Göttingen, and Regen, Germany. Every day, these men and women bring their considerable experience and expertise to the development of optimal products and solutions for the most complex and demanding applications. Micro-optics Qioptiq micro-optics are widely used in medical applications such as endoscopes and ophthalmic systems; and in industrial applications such as inspection and other tasks where their small size and their renowned high-quality is so important. We can provide micro-components with diameter down to 0.3 mm or complete micro-objectives ready for your application (diameters down to 1 mm and fields of view up to 150°) or we can work with your teams to design customized micro-optical lens systems. LASER, OPTICS: COMPONENTS 87 A broad portfolio of high quality standard lenses is ready for industrial inspection tasks Premium items, right off the shelf Qioptiq has the equipment, components and accessories that R&D labs need for their experimental setups. Our precision optics, for example, present a noticeably superior performance. Our offer includes LINOS achromates, singlets, lens systems, F-Theta lenses, laser diode modules, mirrors, polarization optics, zoom and microscope optics, thin film coatings, LINOS Faraday isolators, laser modulators and Pockels cells and more. Qioptiq has a wide variety of precision opto-mechanics including LINOS microbench, nanobench, tube mounting system, positioning systems, mirror mounts, profile and rail systems, optical tables, spectrometers and more. We also have light sources and instruments for the most demanding applications. Optics for medical and life sciences Qioptiq is your optics expert for a large variety of medical and life sciences disciplines: DNA sequencing, flow cytometry, dental imaging, x-ray systems, ophthalmic diagnostics and laser surgery, microscopy, endoscopy and much more. Our worldwide customer base includes both large international firms and renowned small specialist companies. Electrooptical and magnetooptical modulators for applications in laser technology Committed to quality Do you have a specific application or require a customized assembly? Qioptiq is the perfect partner to develop a tailored solution to your unique requirements. Our teams can help you from conception of your instruments through product development to serial production. Discover Qioptiq! Hundreds of companies around the world count on Qioptiq to plan, design, develop and produce the most demanding optical solutions exactly to their specifications. Qioptiq – in Germany and at our other sites around the world – is committed to continuing to invest in the talent and state-ofthe-art equipment needed to meet and exceed the expectations of its global customers. High-end imaging systems help to reduce the x-ray dose to a minimum level QIOPTIQ Königsallee 23 D – 37081 Göttingen Phone +49(0) 0551 - 69 35 -123 Mail sales@qioptiq.de Web www.qioptiq.com INNOVATIONS AND COMPETENCIES IN INDUSTRY 88 SCHOTT AG – Advanced Optics Your partner for Excellence in Optics SCHOTT Advanced Optics offers optical materials, components and filters. With a product portfolio of over 100 optical glasses, special materials, such as active laser glass, IR materials, sapphire, synthetic fused silica, ultra-thin glass, high-precision optical components, wafers, optical glass filters, Advanced Optics develops customized solutions worldwide for applications in areas such as optics, lithography, astronomy, opto-electronics, life sciences, and research. Advanced Optics masters the entire value chain: from customer-specific glass development and its production all the way to high-precision optical product finishing, processing and measurement. Over 125 years ago, the first optical glass revolutionized glass science and technology under the leadership of Otto Schott. ZERODUR®, which made possible completely new applications in astronomy, measurement, etc., through its thermal stability, followed 40 years ago. SCHOTT’s optics department has always been a trailblazer of a multiplicity of applications in different industries. The portfolio is constantly expanding both to meet customer needs and shape market developments. Two examples: Optical Filter Glass and Interference Filters from SCHOTT Filters – Optical filter glasses and interference filters SCHOTT offers one of the largest portfolios of filters in the industry. Various filter types can be obtained by using the different filter glasses or with thin optical layers that are applied under high vacuum with a vapor deposition process. SCHOTT uses different technologies for this, such as reactive vapor depositions and ion plating, and magnetron sputtering in the future. For example, band-pass filters in the UV spectrum range (appr. 200 – 400 nm), which are designed and produced according to customer specifications, are used in the analysis of drinking water and clarified water. Additional applications extend from so-called "i-line filters" (band-pass filters at 365 nm) through filters for fluorescence microscopy and even medical technology. The new N-BK7HT guarantees a minimum transmission of 99.6% at a thickness of 25 mm, and a wavelength of 400 nm. In the visible spectrum range between 400 and 700 nm, the coefficient of absorption is 3 times lower than with standard N-BK7. Heat absorption from powerful light sources and the resulting "thermal lensing effect" is significantly reduced. This means reduced distortion and improved image quality. With the addition of HT glasses to the existing portfolio, more applications can now be achieved when using SCHOTT glass. Optical Glass – HT glasses In further development of the glass portfolio, special variants of glass with significantly increased transmission values have recently been developed. The HT (high transmission) glasses are particularly well suited for application where light takes a long way through an optical component such as prisms of digital projectors. Advanced Optics SCHOTT AG Hattenbergstrasse 10 D – 55122 Mainz Phone +49(0) 6131 - 66 - 1812 Fax +49(0) 3641 - 2888 - 9047 Mail info.optics@schott.com Web www.schott.com/advanced_optics LASER, OPTICS: COMPONENTS 89 II-VI Deutschland GmbH – a Strong Partner for Industrial Laseroptics II-VI Deutschland GmbH – ein starker Partner für Industrielaser-Optiken Plano Convex Optics Plan Konvex Optiken Nd:YAG- / Nd:YLF-laser crystal Nd:YAG- / Nd:YLF-Laserkristall II-VI Deutschland GmbH is the leading company with respect to high-power optics for industrial CO2- and YAGLasers since more than 40 years now. Under industrial conditions Zinkselenide (ZnSe), Zinksulfide (ZnS), Diamond (C), Yttrium-Aluminium-Granat (YAG), Ceramic YAG and Siliciumcarbide (SiC) are produced. Other laser-optical materials – for example Germanium (Ge), Gallium-Arsenide (GaAs), Silicium (Si), Aluminium (Al) and Copper (Cu) – are machined. From those high precision laser optics and optical components are developed and produced for serial application. We produce highly precise laser optics – for example laser resonator optics, focussing lenses and focussing mirrors – with miscellaneous geometries and coatings. Anti reflections coatings (with very low absorption) as well as high reflecting and phase-shifting coatings are manufactured at all locations world wide in unique quality and tested accordingly before they are sent to our customers. For laser scanner systems F-Theta lenses (-systems) as well as tilted mirrors and beam expanders are produced. Metal optics (with sometimes very complex surface geometries) are produced up to a fraction of micrometers by computer controlled diamond machining. II-VI Deutschland GmbH ist seit mehr als 40 Jahren führend auf dem Gebiet der Höchstleistungsoptiken für industrielle CO2- und YAG-Laser. Unter Industriebedingungen werden Zinkselenid (ZnSe), Zinksulfid (ZnS), Diamant (C), Yttrium-Aluminium-Granat (YAG), keramischer YAG und Siliziumkarbid (SiC) hergestellt. Andere Laseroptik-Materialien wie z.B. Germanium (Ge), Galliumarsenid (GaAs), Silizium (Si), Aluminium (Al) und Kupfer (Cu) werden bearbeitet. Aus diesen werden hochpräzise Laseroptiken und optische Komponenten entwickelt und für den Serieneinsatz produziert. II-VI Deutschland GmbH Im Tiefen See 58 D – 64293 Darmstadt Phone: +49 (0)6151 - 8806 - 29 Mail info@ii-vi.de web www.ii-vi.de Wir fertigen hochpräzise Laseroptiken – z.B. LaserResonatorspiegel, Fokussierlinsen und –spiegel – mit den verschiedensten Geometrien und Beschichtungen. Wir bieten z.B. zur Selektion anderer CO2-Laserwellenlängen speziell beschichtete Optiken an (Band-Selective Resonatorcoatings). Antireflex-Beschichtungen (auch mit sehr geringer Eigenabsorption), sowie hochreflektierende und phasenverschiebende Beschichtungen werden an allen Standorten weltweit mit einzigartiger Qualität gefertigt und entsprechend getestet bevor die Produkte beim Kunden eintreffen. Für Laserscanner-Systemen werden F-Theta-Linsen (-systeme), sowie Ablenkspiegel und Strahlaufweiter hergestellt. Metalloptiken (mit u.U. äußerst komplexen Oberflächengeometrien) werden computergesteuert auf den Bruchteil eines Mikrometers genau mit Diamantbearbeitungsmaschinen hergestellt. Damit lassen sich CO2-Laserstrahlen formen – aus einem Gauß-Profil ein Top-Head Profil, aus einem punktförmigen Fokus ein ringförmiger Fokus. INNOVATIONS AND COMPETENCIES IN INDUSTRY 90 OEM Technological Components for Life Science and the Laser Industry Strong power of innovation enables Frank Optic Products to realise individual optic and fibre-optic components and systems primarily for laser engineering. FRANK OPTIC PRODUCTS operates on the international market as a global OEM supplier to the photonic, medical and mechatronic industries and counts as one of the leading technology partners, especially in laser engineering, precision optics, life science, mechanical engineering, astrophotonics, photovoltaics and sensor technology. In order to be able to realise short development and production times, customer ideas are implemented on our company premises using the customers’ designs, great production depth in optics, fibre optics, mechanical engineering, system and device engineering, and electronics. Direct access to all resources required for performance, short production paths and fast implementation significantly reduces development time and costs and guarantees fast delivery. The broad range of FRANK OPTIC PRODUCTS as an OEM supplier to the photonics industry – especially in laser technology – enable customer-specific products to be developed and manufactured fast, flexibly and at low cost all the way from the product idea to serial production. FRANK OPTIC PRODUCT’s knowledge of the interaction of individual components and constructive elements with the laser source and its interfaces provides an elementary advantage for users. The Life Science product portfolio Optical systems for beam guidance, collimation and focusing Precision collimation and focusing of the laser light for the correct, predetermined application, e.g. laser cables and optical systems as important system components in laser medicine in order to apply laser technology, for example in surgery, diagnostics and in dentistry, to meet the needs of the respective patients. • Optical coupling systems including pilot laser sources • Collimation and focusing systems • Fibre-coupled collimation systems • Fibre-coupled zoom lenses for diagnostics and therapy • Lenses and special optical systems Autoclavabel laser cables • Autoclavable application probes in compliance with EN13060-1/2 in processes at 135°C and 3.16 bars absolute, and ETO-sterilisable and biocompatible according to DIN ISO13485 • Autoclavable laser cables and probes for dentistry, surgery and ophthalmology LASER, OPTICS: COMPONENTS 91 The Laser Industry product portfolio – High power laser cable systems • Laser cable for conveying high laser outputs, e.g. 4 to 10-kW laser cables for laser welding in the automotive industry • Multiple laser cables, quartz/quartz-glass fibre-cable systems with fibre core diameters ranging from 50 μm to 1500 μm with a wide variety of claddings and specialist plug-in connector systems Laser and optical components • Laser windows for all solid-state and diode lasers • Flow tubes and flow plates especially for laser engineering in the form of laser tubes with internal and external coatings • Ceramic reflectors, laserceramics® The spectroscopy product portfolio • Fibre arrays and fibre-optic reflection probes and systems, e.g. cross-section converters, light-guide bundles for astrophotonics and biotechnology FRANK OPTIC PRODUCTS GmbH – optische Technologien Heidelberger Str. 63-64 D – 12435 Berlin Phone +49(0) 30 - 5302 49 - 0 FAX +49(0) 30 - 5302 49 - 21 Mail info@fop-berlin.de Web www.frank-optic-products.de INNOVATIONS AND COMPETENCIES IN INDUSTRY 92 From Berlin to Outer Space What was started with two engineering samples back in 2007 has been completed by eagleyard with the shipment of the FLIGHT MODELS for the GAIA mission of ESA. The three years in between were full of technical challenges, deliveries of approx. 200 laser diodes and pan-European cooperations throughout the complete supply chain. Two of the extremely stable DFB laser diodes are used in an interferometric setup in order to monitor and adjust any angle misalignment between the two telescopes at the satellite. The optical path of both GAIA telescopes is composed of six reflectors (M1-M6), two of which are common (M5-M6). The entrance pupil of each telescope is 1.45 x 0.5 m² and the focal length is 35 m. Der optische Pfad der beiden GAIA Teleskope setzt sich aus sechs Reflektoren zusammen (M1-M6), von denen zwei gemeinsam genutzt werden (M5-M6). Die Eintrittsöffnung eines Teleskops ist jeweils 1.45 x 0.5 m² und die Brennweite ist 35 m. In addition to its core tasks as a diode vendor eagleyard significantly contributed in the course of the project by means of its competencies with regards to the electrooptical device characterization and knowledge how to execute environmental tests against common space standards like MIL+ ESCC. After successful delivery of the FLIGHT MODELS in the fall 2010 the official approval by EADS Astrium, the partner responsible for the payload, has been granted and the GAIA mission with the launch scheduled for 2012 is approaching its original task, to create a precise 3D map of more than one billion stars. eagleyard Photonics GmbH Rudower Chaussee 29 D – 12489 Berlin Phone +49(0) 30 - 63 92 - 45 20 Fax +49(0) 30 - 63 92 - 45 29 Mail info@eagleyard.com Web www.eagleyard.com Aus Berlin ins All Es begann mit zwei Engineering Mustern im Frühjahr 2007 und endete im Herbst 2010 mit voll qualifizierten FLIGHT MODELS, die von der eagleyard Photonics für die GAIA Mission der ESA zur Verfügung gestellt wurden. Dazwischen lagen dreieinhalb Jahre voller technischer Herausforderungen, planmäßiger Lieferungen von ca. 200 Laserdioden und europaweiter Kooperationen, die erfolgreich über die gesamte Wertschöpfungskette von der Komponente bis zum Satelliten bewältigt wurden. Zwei der extrem präzisen und langzeitstabilen DFB Laserdioden werden in einer interferometrischen Anordnung genutzt, um kleinste Winkelabweichungen der beiden auf dem Satelliten verankerten Teleskope zueinander zu kontrollieren und gegebenenfalls nachzujustieren. Neben seiner Eigenschaft als Lieferant der bei 850 nm emittierenden Hochleistungs-Laserdioden hat eagleyard darüber hinaus maßgeblich mit seiner Kompetenz auf den Gebieten der elektrooptischen Lasercharakterisierung sowie des umfangreichen Testens nach gängigen Weltraumstandards (ESCC) zum erfolgreichen Verlauf des Projektes beigetragen. Die dabei implementierten Qualitätsverbesserungen dienten primär dem Ziel, den mechanischen Belastungen während eines Raketenstarts, sowie den thermischen Anforderungen an die auf fünf Jahre ausgelegte Raumfahrtmission sowohl am Boden als auch im All standzuhalten. Fully space-qualified-butterflypackaged DFB laser diode in industry compatible 14-pin configuration. Raumfahrtqualifizierte DFB Laserdiode im industriekompatiblen 14-Pin Butterfly Gehäuse. Nachdem die von der eagleyard hergestellten FLIGHT MODELS Ende 2010 offiziell von dem für die Payload verantwortlichen Partner EADS Astrium freigegeben wurden, ist die GAIA Mission mit ihrem geplanten Start in 2012 ihrer eigentlichen Bestimmung einen weiteren Schritt näher gekommen, den L2 Lagrange-Punkt des Sonne-Erde-Gravitationssystems anzufliegen, um von dort eine 3D Landkarte von mehr als einer Milliarde Sternen zu erstellen. LASER, OPTICS: COMPONENTS 93 VERTILAS Laser Technology for Green Photonics Single-Mode VCSEL 10 Gbps LC-TOSA VERTILAS BTJ VCSEL Design VERTILAS GmbH, headquartered in Garching (near Munich), Germany, develops, produces and markets innovative laser diodes for NIR Gas Analysis and Optical Communications. VERTILAS is one of the leading global providers in the field of long-wavelength Vertical Cavity Surface Emitting Laser diodes (VCSEL). The product portfolio offers a wide range of packaging options, such as Transmit Optical Sub-Assemblies (TOSA), incl. an integrated peltier or fiber coupling. VERTILAS highperforming VCSEL technology enables customers to reduce power consumption by up to 50 % and offers signalling rates from 155 Mbps to more than 14 Gbps. VERTILAS’ unique Buried Tunnel Junction (BTJ) laser diode technology offers a wavelength range of 1.3 μm to 2.3 μm, high performance and very low power consumption. Near IR Gas Analysis H2S, H2O, CO, CO2, CH4, NH3, etc. Laser for Gas Analysis TO-39 package with TEC and cap VERTILAS’ VCSEL technology has been proven in several applications, including a variety of demanding spectroscopy applications and communications modules. Furthermore, VERTILAS has excelled in a range of core competencies for components development and manufacturing, including wafer processing, assembly and test and package design. Vertilas GmbH Christian Neumeyr, Chief Executive Officer D – 85728 Garching Phone +49(0) 89 - 5484 - 2010 Mail neumeyr@vertilas.com Web www.vertilas.com High Performance VCSEL Diodes 1270 nm to 2360 nm Ultra Low Power Consumption High Data Rates High Performance Cost Efficient Optical Communications 1310 nm, 1490 nm, 1550 nm, CWDM InP VCSEL Technology Packaging Options 1. Photonic Integration of VCSEL and PLC 2. 10 Gbps Performance INNOVATIONS AND COMPETENCIES IN INDUSTRY 94 OPTICAL+ETHERNET INNOVATION SPEED FOR CUSTOMERS TRUSTED PARTNER The FSP product family provides software-automated Optical+Ethernet networking solutions for access, metro core and regional networks. ADVA Optical Networking is focused on the needs of enterprise and service provider customers deploying data, storage, voice and video applications. Our solutions have been deployed at more than 250 carriers and 10,000 enterprises around the world. www.advaoptical.com DATA TRANSMISSION 95 Integrated and Compact Optoelectronic Devices for Modern Telecommunications-Applications u2t Photonics AG is the leading supplier of optical components for 40G and 100G applications in modern optical telecommunication networks that has grown rapidly with the increasing market over the last few years. As a technology leader, u2t sets the benchmark for higher integration of optical devices in the market. Advanced modulation formats such as differential phase shift keying (DPSK), differential quadrature phase shift keying (DQPSK) and dual-polarisation quadrature phase shift keying (DP-QPSK) at either 40Gbit/s or 100Gbit/s require integrated receivers in order to build economically feasible communications systems and subsystems. u2ts early developments have resulted in timely new product offerings for transponder and system developments. u2t has extended its portfolio even further and is now offering modulator technology complementing its receiver products. New types of highly integrated and compact components for DPSK, DQPSK and DP-QPSK are being introduced. A fully integrated DPSK receiver – u2t’s IDRV series – consists of a DLI (delay line interferometer) and a balanced receiver in a compact package. This significantly reduces size as well as design and production effort for transponder manufacturers. A dual balanced receiver – u2t’s QPRV series – in an ultra small package allows for size reduced DQPSK designs and flexible combination with different DLI types by splicing the components with easy to use ribbon fiber. u2t’s CPRV series is offering integrated coherent receivers for 40 and 100G DP-QPSK applications. The CPRV is a very compact and competitive solution, which is already being delivered in small volume. Finally, u2t’s first modulator product was started to sample earlier this year. Based on developments for microwave photonic applications, the modulators reproduce a modulation characteristic with excellent linearity. The devices uniquely exploit gallium arsenide technology and retain high yield offering good reproducibility and high performance using large scale commercial fabrication methods. u2t’s latest offerings comprise the baseline Mach-Zehnder and I/Q modulators to polarisation multiplexed devices. u2t is working very closely with its customer base to define next generation components and products for early availability while still delivering high performance and quality in volume. u²t Photonics AG Reuchlinstrasse 10/11 D – 10553 Berlin Phone +49(0) 30 - 72 61 13 - 500 Fax +49(0) 30 - 72 61 13 - 530 Mail umbach@u2t.de Web www.u2t.de INNOVATIONS AND COMPETENCIES IN INDUSTRY 96 JENOPTIK AG As an integrated optoelectronics group Jenoptik operates in the five divisions of Lasers & Material Processing, Optical Systems, Industrial Metrology, Traffic Solutions as well as Defense & Civil Systems. Its customers around the world mainly include companies from the semiconductor and semiconductor equipment industry, automotive and automotive supplier industry, medical technology, security and defense technology as well as the aerospace industry. Jenoptik is one of the leading manufacturers of laser technology and optical systems worldwide. In the Lasers & Material Processing division Jenoptik specializes in high-quality semiconductor materials, diode lasers and innovative solid-state lasers and possesses comprehensive know-how in the area of laser processing systems. The Optical Systems division is primarily a development and production partner for optical, micro-optical and optical coating components, optomechanical and optoelectronic assemblies, modules and systems – made of glass, infrared materials and plastics. It possesses outstanding expertise in the development and manufacture of microoptics. The product portfolio also includes systems and components for semiconductor equipment, security and defense technology, life science and lighting applications as well as cameras for digital microscopy. Superb camera technology provides the basis for systems that are making the roads safer all over the world. Speed and red light monitoring systems, OEM products and systems for identifying other violations of road traffic laws are part of the offering from the Traffic Solutions division which is a world market leader in this field. In the Industrial Metrology division Jenoptik also offers high-precision, tactile and non-tactile production metrology, primarily for rotationally symmetric parts. Testing is carried out to determine roughness, contours, shape and dimensions – during the production process (in-process), afterwards (post-process) or in the metrology lab. The Defense & Civil Systems division focuses on military vehicle, rail and aircraft equipment, drive and stabilization technology as well as energy systems. In the business unit Sensor Systems Jenoptik offers laser rangefinder equipment and infrared camera systems for various applications. JENOPTIK AG Carl-Zeiß-Straße 1 D – 07739 Jena Phone +49(0) 3641 - 65 - 0 Fax +49(0) 3641 - 424514 Mail pr@jenoptik.com Web www.jenoptik.com HIGH PRECISION SOLUTIONS AND EQUIPMENTS 97 ZYGO designs, manufactures, and distributes high-end optical systems and components for metrology and end-user applications. ZYGO's metrology systems are based on optical interferometry measuring displacement, surface figure, and optical wavefront. Metrology and optical markets for end-user and OEM applications include semiconductor capital equipment, aerospace/defense, automotive, and research. metrology task, including a low-magnification 1.0X, a highmagnification 100X. The NewView 7000 Series can resolve sub-micron X-Y features, and profile areas on large areas with image stitching on a motorized stage. VeriFire™ Series of Interferometers ZYGO's VeriFire™ Series further exceeds the performance of our industry-standard GPI products with capabilities and NewView 7000 – 3D optical profiler ZygoLOT, based in Darmstadt, as a joint venture between Zygo Corp. and LOT-Oriel GmbH has a long history and high level of competence with optical metrology and as a system integrator understands how to apply ZYGO technologies to best serve our customers all over Europe. Optical Profilometers The NewView 7000 Series of optical profilers are powerful tools for characterizing and quantifying surface roughness, step heights, critical dimensions, and other topographical features with excellent precision and accuracy. All measurements are non-destructive and fast and require no sample preparation. Profile heights ranging from <1 nm up to 15000 μm can be measured at high speed. Based on patented scanning technology, the NewView 7000 Series delivers up to 0.1 nm height resolution – independent of surface texture, magnification, or feature height – all in a single scan, and for every measurement! A complete line of standard and Super-Long-Working-Distance (SLWD) objectives are available to meet almost any features that include mechanical phase acquisition, superior optics quality, high-resolution CCD cameras, vibration correction software, aspheric surface metrology and patented artefact suppression technology. While all VeriFire models can perform standard interferometric metrology, each model offers unique capabilities that set it apart in the industry. ULTRASPHERE/50 Transmission Spheres The new ZYGO Ultrasphere product is designed to enable surface form metrology with an uncertainty in the RMS of ≤3.2 nm (λ/200 at 633nm) when used with a ZYGO interferometer. ZygoLOT GmbH Im Tiefen See 58 D – 64293 Darmstadt Phone +49 (0)6151 - 8806 - 27 Mail info@zygolot.de Web www.zygolot.de INNOVATIONS AND COMPETENCIES IN INDUSTRY 98 Trends in Microscopy How Much “Digital” Do You Really Need? Digital microscopes offer clear advantages for a large number of industrial quality inspections, particularly for 3D surface analysis, fracture analysis, analysis of inclined or vertical surfaces or in situ inspection of large components. However, this does not mean they can simply replace the world‘s traditional microscopes. It’s worth knowing the limitations of digital microscopy as well as the benefits. What is a digital microscope? A digital microscope has no eyepieces to look through. The user views the sample on the screen and analyzes it with the software in a single pass, sitting in a comfortable position. Digital microscopes only offer real value added compared with traditional stereo- or light microscopes if they meet the following requirements: Optimized digital imaging For digital microscopes, 2.11 megapixel CCD cameras that are perfectly matched to the high-resolution optics are quite adequate. They deliver the best possible information yield without producing too much data. If cameras with high megapixel numbers were used, the digital resolution would be far higher than that of the optical system – the image would be larger, but not better. The live image should be displayed with a refresh rate of at least 15 frames per second, which ensures that the image can be viewed in comfort even when the stage is moved. Dynamic viewing of processes or objects Compared with traditional stereomicroscopes, zoom systems have the disadvantage of being unable to provide a three-dimensional image. A digital microscope with a 360° rotary head can more than compensate for this disadvantage, enabling the user to view the sample from all sides and record the panorama view as a movie. Fig.1: Leica digital microscopes with a flexible tilting stand and a rotary xy stage allow reliable analysis of the sides of samples or inclined surfaces. Abb.1: Leica Digitalmikroskope mit flexiblem Kippstativ und drehbarem xy-Tisch erlauben zuverlässige Analysen von seitlichen Probenbereichen oder geneigten Oberflächen. Qualitative and quantitative analysis One of the strengths of digital microscopy is the creation and analysis of 3D surface models. Using the motorized focus drive, an image is recorded in every focal plane in z direction. Then the focus is determined in every single image and for each point. The pixel with the best definition determines the focused texture. This is a fast and precise method of measuring surface topography. Besides 3D profiles it is also possible to measure height profiles, roughness, geometries and volumes. Display of samples with high dynamic range Most digital microscope cameras use 16-bit individual color detection (equivalent to 65,536 colors). For capturing images with a high dynamic range, the so-called High Dynamic Range method is applied, which captures all the natural brightness nuances. With this method, details remain visible even in extremely dark and bright areas. Lean optics for samples that are difficult to access Even inclined or vertical surfaces are no problem for digital microscopes. A flexible tilting stand combined with a rotary xy stage allows reliable analysis in virtually any position. Portable systems enable non-destructive inspection even of stationary objects. Conclusion Digital microscopes are ideal for difficult-to-document samples and fast 3D surface quantification. However, if HIGH PRECISION SOLUTIONS AND EQUIPMENTS 99 Trends in der Mikroskopie Wie viel „Digital“ brauchen Sie wirklich? Fig. 2: The all-in-one-system Leica DVM5000. Streamlined zoom optics reach difficult-to-access surfaces for nondestructive inspection of even the largest stationary parts. Abb. 2: Das tragbare All-in-One-System Leica DVM5000. Seine schlanke Zoom-Optik erreicht auch extrem schwer zugängliche Oberflächen und ortsgebundene Objekte. optical brilliance and variety of contrasting techniques are more important, stereo- or light microscopes are superior. Before investing in a new instrument, therefore, it is worth weighing up the benefits carefully and obtaining impartial advice on the alternatives. Für viele industrielle Qualitätsprüfungen bieten Digitalmikroskope eindeutige Vorteile, insbesondere für 3D-Oberflächenanalysen, Bruchanalysen, Analysen geneigter oder vertikaler Oberflächen oder Vor-Ort-Inspektionen großer Bauteile. Doch sie sind kein Patentrezept, die klassische Mikroskope überall ersetzen können. Deshalb lohnt es sich, die Vorteile wie auch die Grenzen der Digitalmikroskopie zu kennen. Was ist ein Digitalmikroskop? Digitalmikroskope verzichten vollständig auf Okulare. Der Anwender betrachtet die Probe am Bildschirm und wertet sie gleichzeitig über die Software aus – in einer angenehmen Sitzposition. Einen echten Mehrwert gegenüber klassischen Stereo- oder Lichtmikroskopen bieten Digitalmikroskope erst dann, wenn sie folgende Anforderungen erfüllen: Fig. 3: 3D models in seconds: Software visualizes desired 3D models within a few seconds. Further analyses, such as profile measurement or roughness measurement, with just a few mouse clicks. Abb. 3: 3D-Modelle in Sekunden: Die Software visualisiert gewünschte 3D-Modelle innerhalb weniger Sekunden. Weitergehende Analysen wie Profilbestimmung oder Rauigkeitsmessungen erhält der Anwender mit wenigen Mausklicks. INNOVATIONS AND COMPETENCIES IN INDUSTRY 100 Optimierte digitale Bildgebung Für Digitalmikroskope sind 2,11-Megapixel-CCD-Kameras, die perfekt auf die hochauflösenden Optiken abgestimmt sind, völlig ausreichend. Sie liefern bestmögliche Informationsausbeute, ohne zu große Datenmengen zu produzieren. Bei Kameras mit hohen Megapixelzahlen würde die digitale Auflösung die des optischen Systems bei weitem übertreffen – das Bild wird größer, aber nicht besser. Das Live-Bild sollte mit einer Wiederholrate von mindestens 15 Bildern pro Sekunde dargestellt werden, die auch beim Verschieben des Objekttischs ein angenehmes Betrachten der Probe gewährleistet. Dynamische Betrachtung von Prozessen oder Objekten Zoom-Systeme bieten gegenüber herkömmlichen Stereomikroskopen keine räumliche Darstellung. Ein Digitalmikroskop mit einem 360°-Drehkopf kann diesen Nachteil mehr als kompensieren. Die Probe lässt sich damit rundum betrachten, und die Panorama-Ansicht kann als Video aufgenommen werden. Qualitative und quantitative Auswertung Eine Stärke der Digitalmikroskopie ist die Erstellung und Auswertung von 3D-Oberflächenmodellen. Mit Hilfe des motorisierten Fokustriebs wird in z-Richtung in jeder Fokusebene ein Bild aufgenommen, anschließend in jedem Bild und für jeden Punkt die Schärfe bestimmt. Der Punkt mit der besten Schärfe bestimmt die scharf abgebildete Textur. Die Topografie einer Oberfläche lässt sich so schnell und präzise messen. Neben 3D-Profilen können Höhenprofile, Rauigkeiten, Geometrien und Volumina bestimmt werden. Erfassung von Proben mit hohem Dynamikbereich Die meisten digitalen Mikroskopkameras nutzen die 16-BitEinzelfarberfassung (entspricht 65.536 Farben). Für Bilder mit hohem Dynamikumfang wird das so genannte HighDynamic-Range-Verfahren angewendet, das alle natürlichen Helligkeitsunterschiede erfasst. Damit bleiben auch in sehr dunklen und sehr hellen Bereichen Details sichtbar. Schlanke Optiken für schwierig erreichbare Proben Für Digitalmikroskope sind selbst geneigte oder vertikale Oberflächen kein Problem. Ein flexibles Kippstativ in Kombination mit einem drehbaren xy-Tisch erlaubt zuverlässige Analysen in nahezu jeder Position. Tragbare Systeme ermöglichen zerstörungsfreie Inspektionen selbst an ortsgebundenen Objekten. Fig. 5: 3D profiling in all variations: Digital microscopes of Leica Microsystems supply precise 3D profiles of heights, widths and surface structures; display as texture, color depth encoding or grid model; height difference and volume measurements; combined 2D and 3D profiling. Abb. 5: 3D-Profiling in allen Varianten: Digitalmikroskope von Leica Microsystems liefern präzise 3D-Profile von Höhen, Breiten und Oberflächenstrukturen; Darstellung als Textur, Farbhöhenkodierung oder Gitternetzmodell; Höhendifferenz- und Volumenmessungen; kombiniertes 2D- und 3D-Profiling. Fazit Digitalmikroskope sind ideal für schwierig zu dokumentierende Proben und schnelle 3D-Oberflächenquantifizierungen. Stehen jedoch optische Brillanz und die Vielfalt der Kontrastierungsverfahren im Vordergrund, sind Stereo- oder Lichtmikroskope überlegen. Der Investition in ein neues Gerät sollte deshalb eine sorgfältige Evaluation und eine objektive Beratung über Alternativen vorausgehen. Fig. 4: High Dynamic Range (HDR) delivers perfect digital images: Leica Microsystems has long used modern 16-bit individual color detection technology for its digital microscope cameras to exploit the entire dynamic range of the image. This avoids over- or underexposed areas, and difficult surfaces such as polished metal sections are perfectly imaged. Abb. 4: High-Dynamic-Range (HDR) liefert perfekte Digitalbilder: Leica Microsystems setzt bei seinen digitalen Mikroskopkameras schon seit langem die moderne 16-Bit-Einzelfarberfassung ein, um den gesamten dynamischen Bildbereich auszuschöpfen. Damit werden unter- oder überbelichtete Bildbereiche vermieden und schwierige Oberflächen wie Metallschliffe perfekt dargestellt. Leica Microsystems GmbH Corporate Communications Ernst-Leitz-Straße 17 - 37 D – 35578 Wetzlar Phone +49 (0) 6441 - 29 - 2550 Mail kirstin.henze@leica-microsystems.com Web www.leica-microsystems.com HIGH PRECISION SOLUTIONS AND EQUIPMENTS 101 Competence in Spectroscopy Company Profile and Vision With a vision of providing high quality spectroscopic solutions for a multitude of applications, our five founders established the company in 1993. Today, tec5 is operating worldwide with subsidiaries in the USA and UK. Our high quality products for diode-array based UV/VIS/NIR spectroscopy range from standard OEM electronics modules to complete application specific solutions. At tec5 we pair our core competencies in high speed diode array readout technology, optical, mechanical, electronic and software engineering with excellent customer service and support. Our technology extends into many application areas. Industrial optical spectroscopy is instrumental in helping industry maintain optimal quality in the production process and reduce cost. Research and development labs use the technology to create new materials, streamline processes and ensure product efficiency. tec5 is proud to be at the forefront in the field of optical spectroscopy and to provide cutting edge solutions – today and in the future. CompactSpec® and MultiSpec® spectrometer systems Compact and modular assembly Innovative Solutions for the Green Energy Business In various industries such as chemical, pharmaceutical, food, printing, semiconductor, glass, solar, agriculture, optical and lighting, many customers benefit from tec5 products. As an example, tec5 technology is successfully used by leading glass and solar cell manufacturers at various stages of glass coating, wafer and solar cell production for applications like: • Inline process control for the thickness of the antireflection coating on PV wafers The modern diode array technology provides a fast and effective in-line measurement of the reflectance characteristics, color and layer thickness of solar cell coatings. A customized process setup was built in a joint venture with Vitronic and won the Intersolar CellAward 2009. • Inline analysis of wet chemical processes UV/VIS/NIR spectroscopy is a real inline, non-contact method for the analysis of the composition of chemical etching baths in the semiconductor industry. It provides very fast measurements of all calibrated components in one step. MultiSpec®Pro process software shows all concentration values and trends of multiple channels and provides the necessary communication protocols. • Intensity control of sunlight and flash simulators MultiSpec® spectrometer systems are able to record the complete UV/VIS/NIR spectrum from 200 - 1700nm in milliseconds. Therefore, they are outstanding tools for the characterization of sunlight simulators used in the production process. Weatherproof housings allow all-season intensity control of sunlight radiation. This helps to monitor the efficiency of big solar plants more accurately and detailed. • Transmittance and reflectance of coated glass MultiSpec®and CompactSpec®spectrometer systems are used for in-line measurements of coated float glass in transmittance and reflectance. In addition to fixed point or traversing systems tec5 provides flexible laboratory setups for e.g. structured solar glass. tec5 AG Steffen Piecha, Manager Business Unit Systems In der Au 27 D – 61440 Oberursel Phone +49(0) 6171 - 97 58 - 0 Fax +49(0) 6171 - 97 58 - 50 Mail info@tec5.com Web www.tec5.com INNOVATIONS AND COMPETENCIES IN INDUSTRY 102 Green High-Tech: Energy-Efficient Display Technology not only for Mobile Devices Dr. Heidrun Jänchen, Dr. Ralf Waldhäusl, Hans Joachim Stöhr, Thomas Handke Seeing is unbelieving. When they see the projected image for the first time, most people doubt that the Pico projector has a brightness of only 30 lumens. It just looks brighter. The human eye values contrast and especially the high color contrast provided by LED-driven optics much more than mere lumens. The size is even more astounding: only 130 cm3, hardly bigger than a cigarette pack, and about 50 % more including the battery pack that lasts for about 90 minutes. This power source is one of the biggest challenges. It’s no problem to throw 2000 lumens to the wall if you can plug into a power socket. But real, cordless mobility calls for highest energy efficiency that can only be achieved with a sophisticated optical design that uses every lumen from a tiny light source: LED. All optical components must be matched carefully to achieve the highest lumens per Watt ratio. Texas Instrument’s Digital Mirror Device (DMD) provides the best efficiency available in a range of imagers, not needing polarized light and causing the lowest losses due to fill factor, reflectivity and scatter. LED light sources have a big advantage in color sequential projection where red, green and blue sub-images are projected consequently and add up to a full-color image in the brain. They can be switched off when they are not needed because of their extremely short transition time. However, LEDs can contribute even more. The DMD – as every other imager – limits the étendue of the system, a little-known optical quantity that is roughly the product of light emitting area and emission angle. LEDs emit light in an angular range of 180 deg. Hence there is an optimum LED die size for every imager. A smaller LED would produce less light; a bigger one emits excess light that cannot be transferred by the imager. This refers not only to the area of the die but as well to the aspect ratio. Starting from that, projection modules from Sypro Optics produce 11 lm/W, the highest value achieved so far. A new LED technology that generates green light with a violet-emitting die and a green phosphor will increase this value by approximately 30 % as first experiments indicated. This high efficiency enables true mobile projection for video and images but as well for industrial and medical applications. In combination with infrared or UV illumination and imaging, the technology supports various medical inspecFig. 1: Energy consumption of TV sets relative to screen size. Data based on tests shown on http://reviews.cnet.com/ green-tech/tv-consumptionchart/ HIGH PRECISION SOLUTIONS AND EQUIPMENTS 103 tions. Pico projectors can not only project fixed patterns for 3D measurements but as well produce an adapted warped pattern that makes the normal shape of the sample vanish and shows only defects or changes. Adapted, segmented illumination geometry can easily be generated for surface inspection tasks, showing scratches, cracks or bubbles. New applications arise as the performance improves. They can even act as emergency equipment: As ABC News reported, a Samsung SP-H03 projector helped buried Chilean miners wait for their rescue by showing video messages of relatives and football games. Thanks to Sypro Optics’ tiny optical module it fitted into the supply tube. The smallest projection module in the portfolio of Sypro Optics has a volume of only 4.6 cm3 – roughly the size and weight of two sugar cubes, and it brings an 8 lm, 640 x 360 pixel image to the wall with an LED power consumption of only 0.7 W. It fits virtually everywhere, even in a slider phone. Energy efficiency is a virtue not only for Pico projectors but for big video walls in control rooms or advertising as well. Despite the fancy form factor of plasma displays, rear projection (RP) units are the technology of choice where power consumption, rugged design and reliability over a long time are more important. The green factor of Sypro Optics’ rear projection technology was shown in an energy consumption test performed by cnet on 107 TV-sets available in the market – beating competing technologies by a factor of two or – compared to plasma TV – even five. All TV sets were electronically adjusted to the same level of brightness. Efficiency is expressed in power consumption per square meter because for equal perceived brightness, power scales with the luminous area. Long maintenance-free operation is another important merit: LED life-time is as high as 50000 hours (almost six years of continuous operation) today. DMD/LED-based op- tics from Sypro Optics do neither fade with time nor exhibit burn-in effects. In addition, they leave less electronic waste when they finally stop working because the actual imaging unit is much smaller than the screen that is a complex, but easily recyclable sheet of plastic material. About Sypro Optics & Jabil Sypro Optics, based in Jena, was created from a Joint Venture between Jabil Inc. (USA) and Carl Zeiss (Germany). Within Jabil, Sypro Optics is the optical design and technology center. Jabil is an electronics solutions company providing comprehensive electronics design, production and product management services to global electronics and technology companies. It is based in St. Petersburg, Florida, USA. With USD 13.4 billion annual revenue and more than 55 sites on 4 continents, Jabil is the third largest manufacturing services provider. Sypro Optics GmbH Carl-Zeiss-Promenade 10 D – 07745 Jena Phone +49 (0)3641-64-3950 Mail Heidrun_Jaenchen@Jabil.com Web www.syprooptics.com www.jabil.com INNOVATIONS AND COMPETENCIES IN INDUSTRY 104 Visualization Systems for the Fields of Medicine and Industry Allowing access to hidden or difficult to reach areas Whether in the human body, an engine, or a furnace, we explore the insides and make the most diverse environments and structures visible. It is true that while optical products continue to become smaller and more refined, the industry demands operational endoscopes for increasing applications. Unique abilities and possibilities abound within the SCHÖLLY Group, an OEM manufacturer for complex visualization systems. The entire visualization chain, consisting of rigid and flexible endoscopes, endocouplers, and endoscopy camera systems, are developed and produced to the highest standards. In their own respective development departments, optical systems are optimally calculated; ultra-precise components with diameters of 0.2 mm to 22.0 mm are produced with extreme precision. In addition SCHÖLLY, the leading manufacturer of 3D and micro-endoscopes offers its OEM and private label customers individual production options: Prototype production for both large-lot production and small batch series from the in-house department. During production preparation, specialists at SCHÖLLY take care of permits and registrations in the desired areas of operation. Modern production sites in Germany, Switzerland, Bulgaria, and the United States, along with a network of its own service and repair centres, support the global sales network of this international family company. Collaboration with leading institutes and first-rate development companies In order to remain competitive in the challenging markets of the future, we emphasize collaboration with top-rated development companies and leading institutions. One of these is IMTEK, the Institute of Microsystem Technology at the University of Freiburg, Germany, that has offered us access to the latest technologies and research results. In this way, for example, we can conduct materials testing and surface assessments with a scanning electron microscope. Flexible endoscopes used in the field of medicine are currently being tested here for autoclavability. Materials must meet extreme requirements with this form of sterilization: The flexible material, adhesive and HIGH PRECISION SOLUTIONS AND EQUIPMENTS 105 ultra-precise optical components must be able to withstand pressure, vacuum, and temperatures in excess of 134° C. Furthermore, new forms of three-dimensional endoscopy are being researched. SCHÖLLY, the leader in 3D endoscopy, will further expand its leading role in this sector with its own innovations in the coming years. With the aid of state-of-the-art digital technologies, we are currently seeking ways to better interpret images and boost or diminish certain wavelengths. In other words, to manipulate images which are shown on the monitor during an endoscopy in such a way, that the viewer will obtain additional information. We always seek to expand our technical knowledge and offer innovation-oriented companies the possibility to work with us in entering the markets of the future. No one can say for sure what the future of technology and methods will bring. However, with the SCHÖLLY Group's know-how and the strengths of its partners, we are well prepared for it. This is also true for our customers and partners. SCHÖLLY – solutions in sight In the field of microsystem technology, there is hardly anything at present that cannot be simulated by the institute. This allows us, at SCHÖLLY, to come up with solutions to challenges that still lie in the future. This can and will allow us one-of-a-kind possibilities in visualization. Complementary to the possibilities at the research institute, we also take advantage of opportunities with specially-selected development firms. SCHÖLLY FIBEROPTIC GMBH Robert-Bosch-Str. 1 - 3 D – 79211 Denzlingen Phone +49(0) 76 66 - 908 - 0 Fax +49(0) 76 66 - 908 - 380 Mail info@schoelly.de Web www.schoelly-group.com INNOVATIONS AND COMPETENCIES IN INDUSTRY 106 Häcker Automation – 3-D Micro Assembly of Optical Components The shown micro camera – consisting of lens and ccd sensor – was assembled using an integrated alignment-housing process. Typically, such components are part of mobile devices (i.e. cell phones). With 15 years of experience in 3-D Micro Assembly as well as Nano and Micro Dispensing Häcker Automation supplies innovative and reliable solutions for packaging processes in micro optics. Due to very high precision and advanced 3-D assembling functionality, our machines are capable of handling various complex applications – from passive and active alignment of mechanical and micro electronics components to subsequent fixation of these parts. As a specialist for complex problems Häcker Automation manufactures highly scalable and modifiable systems using a modular design approach. It consists of a platform providing standard capabilities as well as more sophisticated equipment, i.e. a unique stereoscopic camera system for automatic 3-D recognition and inspection. In order to meet the requirements of the target process the platform’s functionality can easily be extended by integrating additional devices. Covering a wide range of applications these extension modules are standardized, proven in batch-production and permanently get evaluated and improved. Various options are available for advanced 3-D functionality and therewith assembling of micro optics components. For processing flexible, but precise 3-D adjustment of parts and substrates a 3-D tool head can be integrated as well as a special 3-D carrier. Passive Alignment, i.e. placing a lens at a defined height relative to a laser module, is implemented using a submicron measurement system and our highly precise 3-axes portal. Active Alignment of components on an optical axis or setting elements at a proper focus can be facilitated by more sophisticated equipment, i.e. a collimator unit and a MTF software algorithm. For the fixation of once aligned components, Häcker Automation offers appropriate solutions. The most common way is to apply adhesive and subsequently curing it using UV light generated by an optional light source attached to the tool head. In order to achieve the best possible results Häcker Automation always accompanies its customers during the whole product life cycle. Our services therefore cover various issues, leading from technology consulting, process developing and simultaneous engineering to feasibility studies, prototyping and manufacturing of tailored solutions for our partners. Additionally our newly-built and well equipped Application Centre gives us the opportunity to extensively testing and even small to mid-size job order production. Of course we also provide training and maintenance services for our systems. By using machines manufactured by Häcker Automation customers benefit from utmost precision providing a positioning accuracy of 10 μm @ 3 sigma and – due to our modular system concept – stay very flexible toward changing requirements set by their clients. Häcker Automation GmbH Inselsbergstraße 17 D – 99891 Schwarzhausen Phone +49(0)36259 - 3000 Fax +49(0)36259 - 30029 Mail contact@haecker-automation.com Web www.haecker-automation.com HIGH PRECISION SOLUTIONS AND EQUIPMENTS 107 Precision in Perfection The OWIS GmbH is a worldwide leading manufacturer of state-of-the-art precise components for the optical beam handling and of micro and nano hybrid positioning systems. OWIS products are applied in fields like information and communication technology, biotechnology and medicine, semiconducter and image processing industry as well as mechanical engineering. Founded in 1980, OWIS recognized in time the market demand for special optomechanical parts, a segment where only few suppliers were present. In particular, there were almost no enterprises ready to produce customized solutions in very small lots. From the very beginning, OWIS have concentrated on this market segment and have ever since continued to specialize themselves. Furthermore, OWIS belonged to the first companies having system components set up on profile rails in their stocks. The fact that this system is still very popular in all laboratories worldwide and that it is still regularly used, confirms its high acceptance. In the meantime, nearly all manufacturers within this sector offer a similar rail system. Today, OWIS has 50 employees and is present in many countries worldwide through own sales force or agencies. In Germany, distribution is made by the own sales force. Individual solutions can be also locally worked upon with the customers. Many customers from universities, laboratories and industrial enterprises appreciate OWIS because of their competence and reliability and because of the quality and the compatibility of their products. Quality and precision have for OWIS top priority, not at last ensured by the certification in accordance with DIN EN ISO 9001. OWIS owe their successful market presence to their flexibility and their fast reaction to global market development trends. OWIS GmbH Im Gaisgraben 7 D – 79219 Staufen Phone +49(0) 76 33 - 95 04 - 0 Fax +49(0) 76 33 - 95 04 - 440 Mail info@owis.eu Web www.owis.eu INNOVATIONS AND COMPETENCIES IN INDUSTRY 108 Hexapod: Precise 6-Axis Motion in a Small Package Micron-level positioning accuracy is one of today's requirements in many areas of automation technology. Examples can be found in electronics fabrication, as well as in medical technology, metrology, biotechnology and photonics. Parallel kinematics systems have several advantages over stacked multi-axis positioners. All six actuators act on a joint platform, which keeps the moved mass low. Moreover, there is no summation of the lateral runout and tilts of individual axes. The rotation point (pivot point) can be selected as desired via software commands and thus remains independent of the movement. Physik Instrumente (PI) is one of the leading players in the global market for precision positioning technology and offers a large variety of hexapod systems for load capacities from a few kilograms up to several tons. Miniature Hexapod with Great Freedom of Movement The miniature M-810 hexapod (Fig. 1) takes up only minimal installation space. With a diameter of only 10 cm and a height of 118 mm it provides travel ranges up to 40 mm in the XY-plane and up to 13 mm in the Z-direction. The highprecision brushless special DC motors and high-resolution encoder give each individual strut a positioning resolution of a mere 40 nm. The mini-hexapod reliably positions loads up to 5 kg and achieves speeds of up to 10 mm/s. Despite its compact size, the necessary driver electronics have been integrated into the base platform of the mini-hexapod. The control is 100% compatible with all previous hexapod models and is conveniently executed via an Ethernet connection. As with all PI hexapods, the position can be entered with commands in Cartesian coordinates. Precision Alignment System especially for Photonics The F-206.S HexAlign Hexapod (Fig. 2) is a highly accurate micropositioning system for complex multi-axis alignment tasks. Unlike hexapods with variable-length actuators, the F-206 features constant-length struts and friction-free flexure guides. This gives the F-206 even higher precision than other hexapod designs. Optional internal and external photometers are available. Both types are fully integrated with the controller hardware and with routines designed for automatic alignment of collimators, optical fibers and arrays. Fig.1: The miniature Hexapod M-810 provides long travel ranges despite its compact design (Physik Instrumente (PI)) Fig.2: The F-206.S Hexapod comes with a digital 6D controller and comprehensive software (Physik Instrumente (PI)) Physik Instrumente (PI) GmbH & Co. KG Auf der Römerstr. 1 D – 76228 Karlsruhe/Palmbach Phone +49(0) 721 - 4846 - 0 Fax +49(0) 721 - 4846 - 100 Mail info@pi.ws Web www.pi.ws PI in Brief Over the last four decades, the Karlsruhe-based company PI has become the leading manufacturer of nanopositioning technology. PI is a private company with healthy growth, more than 500 employees world-wide and a flexible organization which enables PI to fulfill almost any request in the field of innovative precision positioning technology. All key technologies are developed in-house. This means that every phase from the design right down to the shipment can be controlled: The precision mechanics and the electronics as well as the position sensors and the piezo ceramics or actuators. The latter are produced by the subsidiary company PI Ceramic. HIGH PRECISION SOLUTIONS AND EQUIPMENTS 109 LT Ultra-Precision Technology GmbH Founded in 1995, LT Ultra-Precision Technology GmbH has become one of the leading manufacturers of high performance metal optics, ultra precision machines and aero-/ hydrostatic bearing components as well as beam delivery components. In addition to the serial production of optical surfaces on non ferrous metals, plastics and crystals with shape accuracies in the range of 0.0001 mm, customer specific solutions are elaborated in close co-operation with our customers. Extensive consulting-, support-, trainingand after-sales services round out the program. LT Ultra-Precision Technology GmbH has quickly gained reputation among various national and international companies in the field of laser-machining and metrology. It is the same with aero-/hydrostatic stages, spindles and ultra- MMC 1100 Z2 UP-Machining center UP-Bearbeitungszentrum precision machines. These are often customer specific solutions for the semiconductor- or the optical industry and specifications are derived from the parts to be machined. In this way, know-how in the field of air- and hydrostatic bearings, the machining of metal optics and the manufacture of ultra-precision machines complement each other to the benefit of our customers. Air bearings and metal optics Luftlager und Metall-Optiken Obwohl erst im Jahre 1995 gegründet, hat sich LT UltraPrecision Technology GmbH mittlerweile zu einem der führenden Hersteller von Hochleistungs-Metalloptiken, Ultrapräzisionsmaschinen, aero- und hydrostatischen Lagern und Führungen sowie Strahlführungskomponenten entwickelt. Neben der Serienfertigung von optischen Oberflächen auf NE- Metallen, Kunststoffen und Kristallen mit Formgenauigkeiten im Bereich von 0.0001 mm, werden in Zusammenarbeit mit den Kunden auch spezifische Lösungen innovativ erarbeitet und realisiert. Eingehende Beratung, Betreuung, Schulung und ein umfangreicher After-Sales-Service runden das Programm ab. Die LT Ultra-Precision Technology GmbH hat sich in kürzester Zeit bei vielen nationalen und internationalen Firmen im Bereich der Laser- Materialbearbeitung und der Messtechnik einen Namen als zuverlässiger Lieferant und Partner gemacht. Gleiches gilt für den Bereich der aero- bzw. hydrostatisch gelagerten Rundtische und Linearführungen. Komplexe Ultra-Präzisionsmaschinen sind oft kundenspezifische Sondermaschinen für die Halbleiter- und Optikindustrie, deren Spezifikationen wesentlich von den Bauteilen bestimmt werden, die später mit diesen Maschinen bearbeitet werden sollen. So ergänzen sich Know-How aus Luftlagerfertigung, Optikherstellung und dem Bau von Ultrapräzisionsmaschinen zum Vorteil unserer Kunden. LT Ultra-Precision Technology GmbH Aftholderberg, Wiesenstr. 9 D – 88634 Herdwangen-Schönach Phone +49 (0)7552 - 40599 - 0 Fax +49 (0)7552 - 40599 - 50 Mail info@lt-ultra.com Web www.lt-ultra.com INNOVATIONS AND COMPETENCIES IN INDUSTRY 110 Nessy II – the Dedicated Sputtering System for EUV Applications Fig. 1 shows the rear view of the Nessy II-sputtering system. The large chamber is equipped with cryo – pumping system, as well as the load lock chamber on the right side, to achieve the best vacuum conditions Abb. 1 zeigt die Rückansicht der Nessy II-Sputteranlage. Die große Beschichtungskammer ist ausgestattet mit Cryo-Pumpen und einer Beladestation auf der rechten Seite, um die besten Vakuum-Konditionen zu erreichen. Over many decades Leybold Optics has made a name for itself as supplier of high-quality coating systems in the optics industry. We are operating worldwide with daughter companies in Europe, Asia and the USA. With the development of the Nessy II-sputtering system Leybold Optics has done the next step in our engagement for coating system for photolithography applied for the masking for semiconductor chips. We are since a decade successful with special evaporation systems for DUVapplications, for 193 nm. Nowadays the state of the art in photolithography is to use light at 193 nm in DUV-wavelength range. To achieve higher resolution and smaller structures, and by this also a higher packing density of transistors and other units on a chip the development is underway to use X-rays with wavelength of 13 nm in EUV-range. The necessary components for the photolithography units are collector mirrors with a special coating which are able to achieve high reflectance at 13 nm, have a long life time in operation and can withstand temperatures over 600° C. Leybold Optics has developed a unique sputtering system for these special coatings, the Nessy II. The coating system can be equipped with up to 6 sputtering cathodes to coat the Mo- and Si-layers for the mirror coatings. Other materials can be used for interdiffusion barrier layers and capping layers to achieve a long life time and high temperature stability. Curved substrates with up to a diameter of 660 mm can be coated with highest accuracy. Special velocity profiles for the rotation of the substrates will be applied to achieve the necessary high uniformity also on the curved collector mirrors. The machine is equipped with a load lock chamber, while the sputtering chamber is all the time under vacuum with base pressure below 1*10-8 mbar. Special sputtering cathode configurations has been developed to be operated at sputtering pressures below 1*10-3 mbar to achieve high purity of the coated materials. Reflectance values of more then 68 % at 13 nm has been achieved already. The layer systems consist of more then 100 layers with individual layer thicknesses of few nanometres. This requires a high precision, high stability and repeatability of the coating process. Leybold Optics succeeds to develop and to introduce this unique sputtering system already to the market, prepared for the next generation EUV-Lithography. HIGH PRECISION SOLUTIONS AND EQUIPMENTS 111 Nessy II – die maßgeschneiderte Sputter-Technologie für EUV Anwendungen Fig.2 shows a the front view of the Nessy II. On the left side the door of the load lock chamber is visible for loading substrates up to a diameter of 660 mm. Abb. 2 zeigt die Vorderansicht der Nessy II – Anlage. Auf der linken Seite ist die Tür der Beladungskammer sichtbar, die ein Beladen der Beschichtungskammer für Substrate bis zu einem Durchmesser von 660 mm erlaubt. Seit Jahrzehnten hat sich Leybold Optics, mit Tochtergesellschaften in Europa, Asien und den USA, weltweit einen Namen als Hersteller von qualitativ hochwertigem Beschichtungssystemen für die optische Industrie gemacht. Mit der Entwicklung der Nessy II-Sputter-Beschichtungsanlage hat Leybold Optics den nächsten Schritt getan bei der Herstellung von Beschichtungssystemen für die Photolithographie, angewandt bei der Maskierung von Wafern zur Herstellung von Halbleiterbauelementen. Wir produzieren seit über 10 Jahren erfolgreich spezielle Beschichtungssysteme für DUV-Anwendungen bei 193 nm. Derzeit wird in der Photolithographie Licht von 193 nm im DUV-Wellenlängenbereich verwendet. Um eine höhere Auflösung, kleinere Strukturen und eine höhere Packungsdichte von Transistoren und anderen Bauelementen zu erreichen, verwendet man Röntgenstrahlen mit einer Wellenlänge von 13 nm im EUV-Wellenlängenbereich. Die notwendigen Komponenten für die Photolithographie-Anlagen sind Kollektorspiegel mit einer speziellen Beschichtung, die eine hohe Reflektivität bei 13 nm, Temperaturen über 600° C im Betrieb erreichen und eine hohe Lebensdauer haben. Leybold Optics hat Nessy II, eine besondere Sputter-Beschichtungsanlage für diese Spiegelbeschichtungen entwickelt. Diese Beschichtungsanlage kann mit bis zu 6 Sputter-Kathoden ausgerüstet werden, um die Mo- und Si-Schichten für die Spiegelbeschichtung aufzubringen. Andere Materialien können ebenso verwendet werden für Interdiffusion-BarriereSchichten und für Capping-Schichten, um eine hohe Le- bensdauer und eine hohe Temperaturstabilität zu erreichen. Gewölbte Substrate mit einem Durchmesser bis 660 mm können mit höchster Genauigkeit beschichtet werden. Spezielle Geschwindigkeitsprofile für die Rotation der Substrate machen auch eine genaue Schichtdickenverteilung auf den gewölbten Kollektor-Spiegeln möglich. Die Anlage ist mit einer Schleusenkammer ausgestattet, während die Beschichtungskammer mit einem Enddruck von kleiner 1*10-8 mbar unter Vakuum gehalten wird. Verwendet werden für diese Anwendung speziell entwickelte Sputterkathoden, die auch bei Drücken unterhalb von 10-3 mbar betrieben werden können, um höchste Reinheit der Beschichtung zu gewährleisten. Hohe Reflektionswerte von mehr als 68 % bei 13 nm sind bereits möglich. Das aufgebrachte Schichtpaket besteht aus mehr als 100 Schichten mit Schichtdicken von nur einigen Nanometern für die jeweilige Schicht. Dies erfordert eine hohe Präzision, hohe Stabilität und Reproduzierbarkeit des Beschichtungsprozesses. Leybold Optics hat erfolgreich dieses besondere Beschichtungssystem entwickelt, auf den Markt gebracht und ist bereit für die nächste Generation der EUV-Photolithographie. LEYBOLD OPTICS GmbH Dr. Karl Matl Siemensstrasse 88 D – 63755 Alzenau Phone +49 (0) 6023 - 500 - 467 Fax +49 (0) 6023 - 500 - 483 Mail karl.matl@leyboldoptics.com Web http://www.leyboldoptics.com INNOVATIONS AND COMPETENCIES IN INDUSTRY 112 Electron-Beam Lithography for Optical Application The Vistec Electron Beam Lithography Group is a world leader in the design and manufacturing of electronbeam lithography systems and provides leading edge technology solutions for a wide range of applications. The Group provides systems to both to key semiconductor manufacturers as well as to Universities and Centres of Excellence. The application areas span a wide range of existing and emerging semiconductor and nanotechnology applications including silicon direct write, compound semiconductor, mask making, advanced research, integrated optics and several new markets. In addition to their production facilities in Germany and the US, the Group also maintains service and support centres in the USA, Europe, China, Japan, Taiwan and Korea. Operating under the umbrella of Vistec Electron Beam Lithography Group the latter consists of two companies / business unites: Vistec Electron Beam GmbH, which produces Variable Shaped Beam lithography systems – located in Jena, Germany and Vistec Lithography, Inc., manufacturing Gaussian Beam lithography systems – located in Watervliet, NY, USA. The two companies (Jena/Germany and Watervliet/ USA), benefit from the synergies between leading edge researchers, small and mid-sized equipment and supplier companies and key semiconductor manufacturers in their neighbouring areas. They have a brilliant record as experienced developers and manufacturers of electron-beam lithography systems. Their roots go back to Carl Zeiss and Cambridge Instruments in the 1960s. Optics became an important technology in our daily life, and will play an even more important rule in the future. Electron-beam lithography, with its highest resolution capability and flexibility, is one of the technologies allowing the manufacturing of optical elements with new optical properties. However, special requirements including positioning optimization and accuracy of critical structures dimensions, along with high throughput and stability over long exposure times and the capability to handle large data volumes are linked with optical applications. With a team of highly motivated employees, excellent researchers and engineers Vistec has worked hard to ensure the outstanding performance of their electron-beam lithography systems, thus fulfilling the challenging requirements of its customers. Source: Fraunhofer IOF Vistec Electron Beam Lithography Group Vistec Electron Beam GmbH Goeschwitzer Strasse 25 D – 07745 Jena Phone +49(0) 3641 - 651900 Fax: +49(0) 3641 - 651922 Email electron-beam@vistec-semi.com Web www.vistec-semi.com Vistec Lithography, Inc. 125 Monroe Street Watervliet, NY 12189-4015 USA Phone +1 518 - 874 3000 Fax +1 518 - 874 3189 Email electron-beam@vistec-semi.com Web: www.vistec-semi.com HIGH PRECISION SOLUTIONS AND EQUIPMENTS 113 BERLINER GLAS GROUP – Your Partner for Optical Solutions BERLINER GLAS GROUP – Your Partner for Optical Solutions The Berliner Glas Group is one of the leading European providers of optical key components, assemblies and systems as well as high-quality refined technical glass. With our understanding of optical systems and optical production techniques, we develop and integrate optics, mechanics and electronics into innovative system solutions. Our markets: Medical Technology, Semiconductor, Geosystems, Metrology, Analytics, Space, Defense, Display. As an owner-managed, medium-sized company with around 950 employees, we offer our customers tailor-made, market-driven solutions of the highest quality. Engineering • System engineering • Optical and mechanical design • Coating design • Customer-specific metrology Key-Components • Spherical lenses • Aspherical lenses • Cylindrical lenses • Plano optics • Prism systems • Microstructuring • Coating: coating design, spectral range: VUV, DUV, UV, VIS, NIR, IR correspondingly approx. 130 – 6,000 nm • Anti-reflex coatings • Filter • Mirror • Beam splitter/combiner • ITO coating • Holographic gratings Assemblies Systems • Optical assemblies and systems (cemented beam splitter, prism systems, doublets, triplets, step-systems) • Optomechanical assemblies and systems • Electrooptical systems • Lens systems • Objectives, zoom systems • Measuring systems • Cameras • Laser systems • Light sources • Lighting systems Berliner Glas KGaA Herbert Kubatz GmbH & Co. Waldkraiburger Straße 5 D-12347 Berlin Phone +49 (0)30 - 60905 - 0 Fax: +49 (0)30 - 60905 - 100 Mail photonics@berlinerglas.de Web www.berlinerglas.com Die Berliner Glas Gruppe ist einer der führenden europäischen Anbieter optischer Schlüsselkomponenten, Baugruppen und Systeme sowie hochwertig veredelter technischer Gläser. Mit unserem Verständnis für optische Systeme und optische Fertigungstechnik entwickeln und integrieren wir für unsere Kunden Optik, Mechanik und Elektronik zu innovativen Systemlösungen. Unsere Märkte: Medizintechnik, Halbleiterindustrie, Geodäsie, Messtechnik, Analytik, Weltraumtechnik, Verteidigung, Displays. Als eigentümergeführtes, mittelständisches Unternehmen mit rund 950 Mitarbeitern bieten wir unseren Kunden maßgeschneiderte und marktgerechte Lösungen von höchster Qualität. Entwicklung • Systementwicklung • Optik- und Mechanikdesign • Beschichtungsdesign • produktbezogene Messtechnik Schlüsselkomponenten • Sphärische Linsen • Asphärische Linsen • Zylindrische Linsen • Planoptik: Fenster, Prismen und Prismensysteme • Mikrostrukturierung • Beschichtung: Beschichtungsdesign, Spektralbereich: VUV, DUV, UV, VIS, NIR, IR entsprechend ca. 130 – 6.000 nm • Antireflexschichten • Filter • Spiegel • Strahlteiler/ -kombinierer • ITO-Schicht • Holografische Gitter Baugruppen Systeme • Optische Baugruppen und Systeme (verkittete Strahlteiler, Prismensysteme, Doublets, Triplets, Stufensysteme) • Optomechanische Baugruppen und Systeme • Elektrooptische Systeme • Linsensysteme • Objektive, Zoomsysteme • Messsysteme • Kameras • Lasersysteme • Lichtquellen • Beleuchtungssysteme Market s and N etwork s MARKETS AND NETWORKS 116 German Society of Applied Optics Deutsche Gesellschaft für angewandte Optik e. V. (DGaO) Interface between optics experts from science and industry More than 100.000 employees and an annual turnover of about 16 billion Euros make the optical technologies to be one of the most important fields for the future of German economy. The essential part to promote this area is the exchange of knowledge and experiences between photonics and optics experts from industry on one side and from research laboratories and universities on the other side. Since its foundation in 1923 the German Society of Applied Optics (DGaO) is committed to this task. Apart from different working groups and meetings on a national level, DGaO endeavors this interfacing idea more and more also on a European level. Key-role to establish applied and close-to-industry research problems in Europe As third biggest “Branch” of the European Optical Society (EOS), after the French and the British optical society, DGaO influences and supports optical technologies and science on a European level. Due to a very strong optics and photonics industry in Germany, DGaO plays a key-role in establishing applied and close-to-industry research problems in optics in a European context. Preservation of the level of optics education and further training Education and further training in the field of the optical technologies is another element, which especially in a European context becomes more and more important. Herein, DGaO considers itself to be partner and intermediary between educational institutions and institutions of further training on one side and the needs of the labour market on the other side. The preservation of the currently very high level of optics education and further training, especially regarding the new academic degrees according to the Bologna process, is a great concern of DGaO. Topic biophotonics Besides further topics as optical metrology and micro-optics, the area of biophotonics is of special interest for DGaO. The corresponding working group is headed by the internationally renowned scientist, Prof. Gert von Bally. The goal of this working group is the installation of a communication platform for biophotonics to intensify connections to other national and international scientific societies. Due to its currentness this activity has also been support within the 6th European frame program "Life Science, Genomics and Biotechnology". Apart from researchers from universities and research institutions within this working group there are members from industry such as Karl Storz Endoskope, Leica Microsystems, Richard Wolff GmbH, coherent Deutschland GmbH, sartorius AG und lighttrans GmbH und zett optics GmbH. Emerging topics An emerging topic will be the area of illumination engineering including the related light sources such as LEDs and OLEDs. Due to new scientific results in the field of photonic crystals and meta-materials and the interest of various German material producers make DGaO to focus more on topics like optical materials and optical production engineering. MARKETS AND NETWORKS 117 Diffraction grating on a concave spherical mirror manufactured by an integrated ultra-precision milling and laser ablation process. The research to achieve these results, was part of “Kompetenzdreieck Optische Systeme”, a project within the BMBF-program “Spitzenforschung und Innovation in den neuen Ländern”. (R. Kleindienst, et al., “ Reflective hybrid optical components – Functionalization of non-planar optical surfaces using direct ps-laser ablation”, Annual Meeting of the European Optical Society (EOS), Paris, 26.-29.10.2010). Source: Prof. Dr. Stefan Sinzinger, TU-Ilmenau (Germany). Optical assembly for application in semiconductor industry (Source: Berliner Glas KGaA) Annual Meetings The Annual Meeting is the most suitable forum to discuss and address the topics mentioned above to the corresponding audience. Being frequented by several hundreds of scientists and engineers, this Annual Meeting typically takes place in spring in the week after Whitsuntide. The meeting is accompanied by a small trade-show, where companies and organisations are invited to present their products or services for very moderate fees. 112th Annual Meeting of the DGaO in Ilmenau (Thuringia) The 112th Annual Meeting will take place from June 14th-18th 2011 at the Technical University of Ilmenau (Thuringia). Based on the application fields “medical engineering/health”, “production engineering” and “envi- ronmental engineering” the focus will be on the following specific topics: • Optical and opto-mechanical microsystems • Optical micro-manimulators • Modelling and simulation of optical systems • High precision optical metrology /hyper-spectral imaging • New optical materials Short oral presentations (12 minutes) and poster presentations are invited, concerning all aspects of Applied Optics, and preferably the above mentioned topics. The meeting language is German and English. Submission of the contributions should be made before January, 14th 2011 on www.dgao.de. Photonic crystal fibers with various geometries (Source: Prof. Dr. Jörg Bartelt, IPHT Jena) Prof. Dr. Michael Pfeffer President of the German Society of Applied Optics (DGaO) c/o Hochschule Ravensburg-Weingarten Dogggenriedstraße Postfach 1261 D – 88241 Weingarten Phone +49(0) 751 - 501 - 9539 Fax +49(0) 751 - 501 - 9874 Mail dgao-sekretariat@dgao.de pfeffer@hs-weingarten.de Web www. dgao.de MARKETS AND NETWORKS 118 Optical Technologies – Market Forces Dictated by Light Laser2009 Photonics Forum Halle B1 Laser2009 Halle B1 Cross-sectional technologies helping to secure the future Optical technologies are regarded as pacemaker technologies and are bringing about important product innovations in industries such as automobile construction, shipbuilding, mechanical engineering, aerospace, microelectroncs, pharmaceuticals and medicine. As a cross-sectional technology, photonics is used in the areas of production engineering, imaging, measuring technology, medical technology, life sciences, lighting engineering, power engineering, environmental technology, data and communication technology, research and science. Since, however, the range of applications is continually increasing, photonics can look forward to a glittering future. Expanding world market – photonics in Germany and internationally Optical technologies are a highly efficient branch of industry in Germany. 128,000 people were directly employed in the area of optical technologies in Germany in 2008. Around 1 million jobs in the manufacturing industry actually depend indirectly or directly on optical technologies. According to assessments by the German Federal Ministry for Education and Research, products to the value of € 23.1 billion were manufactured in 2008 and over 65 % of them were exported. The world market for OT products amounted to € 256 billion in 2008. Germany’s share of production in this figure was 9 % in 2009. A worldwide annual growth rate of around 8 % is expected up to 2015. Thanks to substantial investments in research and development amounting to 9.7 % of total turnover in Germany, the industry has established a strong position in international competition. Networking platforms as important factors for economic development As highly promising key technologies, optical technologies represent a strong branch of the economy for the industrial location Germany and play an important role in production and research all over the world. In addition to general economic conditions and the promotion of industrial locations and research, the transfer of know-how regarding research findings and applications is extremely important for the positive development of the photonics industry. The economic importance of photonics is furthered by international information and networking platforms. Experts and users from many different areas of photonics in research and industry attend congresses and industry marketplaces in order to exchange know-how and present innovations to specialists. Most important marketplaces for the photonics industry in Munich and Shanghai in 2011 The world’s leading trade fair LASER World of PHOTONICS in Munich and LASER World of PHOTONICS CHINA in Shanghai occupy a central leading role as marketplaces for the photonics industry. They are the world’s most important forums for photonics. Both trade fairs complement one another in their global distribution and together have a great leverage effect for photonics and its worldwide users. LASER World of PHOTONICS CHINA firstly stimulates significant market developments in China and for the whole MARKETS AND NETWORKS 119 Laser2009 Eingang West Laser2009 Congress of Asia. Secondly, it opens up new markets in Asia for European manufacturers. The global industry meeting-points allow the photonics industry to profit from global trends and knowledge diversity, and also position itself internationally. They therefore enable exhibitors to cover the world market for optical technologies. LASER World of PHOTONICS in Munich: Most important international industry meeting-point LASER World of PHOTONICS has been the world’s leading event for optical technologies since 1973. The world’s leading trade fair will be held for the 20th time in Munich from May 23 to 26, 2011. As the leading international platform for lasers and photonics, it will present the entire spectrum of optical technologies together with the concurrent World of Photonics Congress. The World of Photonic Congress is now the most important congress for photonics in the whole of Europe. It acts as an international network platform and combines under one roof six conferences which are organized by leading international bodies. 1,034 exhibitors and 25,365 visitors attended LASER World of PHOTONICS in 2009. 57 % of exhibitors and 51 % of visitors came from abroad. This high internationality emphasizes the international market leadership of LASER World of PHOTONICS. The complete range of exhibits, the presence of every key player in the industry and the close orientation of the trade fair towards applications underline its leading international role. The main exhibition areas are lasers, optronics, lasers and laser systems for production, biophotonics, life sciences, optics, imaging and measuring technology. LASER World of PHOTONICS CHINA: Leading role in Asia LASER World of PHOTONICS CHINA, which is becoming the leading photonics trade fair in Asia, will be held at Shanghai New International Expo Center from March 15 to 17, 2011. It is already the main trade fair for lasers and photonics in the People’s Republic of China. It is experiencing high growth in all areas after only being staged for five times. In 2010 the trade fair attracted 275 exhibitors (+ 25 %) from 17 countries and 25,243 visitors (+ 15 %). The amount of exhibition space increased to 11,500 square meters (+ 27 %). The high demand highlights the economic importance of the trade fair as a marketplace throughout Asia. The main exhibition areas are lasers and optronics, lasers and laser systems for production engineering, optics and manufacturing of optics, sensors, testing and measurement, and accessories and services. In 2011 the trade fair will feature an Optical Information and Communications Technology Pavilion for the first time. Messe Muenchen International Press contact Frau Claudia Huber Messegelaende D – 81823 Muenchen Phone +49(0)89 - 949 - 20862 Mail claudia.huber@messe-muenchen.de Web www.messe-muenchen.de ISSN 2191-7191