Organic Models
Transcription
Organic Models
ORGANIC MODEL BUILDING & HOMOLOGOUS SERIES In this experiment, you will build models for molecules in which carbon atoms may bond with each other as well as with atoms of other elements. Each carbon atom, however, may make only four covalent bonds. When carbon atoms bond with each other, they form a carbon chain. Compounds containing carbon chains may become a homologous series. A homologous series is a set of compounds that conform to a general mathematical ratio and general structure. As you build models of the members of some homologous series, you will discover some series contain functional groups. A functional group is responsible for characteristic properties and reactions. You can recognize a functional group by the collection and arrangement of specific atoms. You will learn more about the characteristic functional groups in this unit. Equipment and Supplies: per Lab Station ball and stick molecular model kit What to Do Obtain a ball and stick model kit. The instruction sheet in the box lists the color code for the balls. Let one ball represent an atom. A stick is used to show one covalent bond. Springs are used to represent two or more bonds between the same two atoms. 1. 2. Make a model of methane, CH4. Record the structural formula in Data Chart I. 3. Make models of successive members of the series in which the hydrocarbon, methane, is the first member. (A hydrocarbon is a compound composed of hydrogen and carbon only.) Record on data table. DATA CHART I Alkane Series CnH2n+2 Member Molecular Formula Structural Formula Name 4. First methane Second ethane Third propane Fourth butane Study Data Chart I and answer the following questions: (a) For every additional carbon atom, how many hydrogen atoms are needed? (b) The consecutive members of the homologous series differ by —CH2. Does ethane belong to a homologous series? Select two carbon atoms and connect them by two springs. Complete the model by adding as many hydrogen atoms as possible. The model represents a molecule of ethene, also called ethylene, the first member of the Alkene Series. Record the structural formula in Data Chart II. 5. DATA TABLE II Alkene Series Member Molecular Formula CnH2n Structural Formula First Name ethene (ethylene) Second propene (propylene) Third butene (butylene) 6. Continue to add carbon atoms until all of the information for Data Chart II has been found. Keep the pair of double-bonded carbon atoms at one end of the molecular model. The other carbon bonds are single bonds 7. Study Data Chart II and answer the questions. Are the members of the Alkene Series members of a homologous series? How do you know? 8. Make a model for a methanol molecule. Methanol is an alcohol whose structural formula is H │ The O-H is known as a H ― C― O ―H functional group; it is found in all alcohols. │ H 9. Continue to add carbon atoms until all of the information for the Data Chart below has been found. Keep the —0-—H group in all of your models. Write the structural formulas for the models you make. Member Molecular Formula DATA CHART Structural Formula Name First Methanol (methyl alcohol) Second Ethanol (ethyl alcohol) Third Propanol (propyl alcohol) Fourth Butanol (butyl alcohol) 10. Study the models of the alcohols you made. Are they members of a homologous series? Explain ** REMOVE ALL PEGS AND SPRINGS FROM THE BALLS. PUT AWAY THE BALL & STICK MODEL KIT AND CONTINUE TO WORK ON THE BALANCE OF THE LAB. Questions to Answer 1. How is the presence of only single-bonded carbon atoms in a homologous series indicated in the name of (a) the series? (b) the name of a member of the series? 2. How is the presence of one double bond in the carbon chain indicated in the name of a homologous series? 3. Study the Data Chart for the Alkene Series. (a) Is there any member of this series that does not have twice as many hydrogen atoms as carbon atoms? (b) The general formula for the Alkene Series is CnH2n. What does this formula tell you? Is the general formula a formula for a single compound or does it apply to every member of the series? 4. Study the Data Chart for the Alkane Series. (a) In the formula for ethane, are there exactly twice as many hydrogen atoms as carbon atoms? Are there more than twice as many carbon atoms? If so, how many? (b) How many carbon atoms are in a molecule of propane? How many hydrogen atoms? Do you think that the general formula for the Alkane Series might be CnH2n ? Explain. 5. The general formula for the Ethyne Series is CnH2n-2. What does this formula tell you about the formula for any member of this series? 6. The name ending of the Alkyne Series indicates a triple bond in the carbon chain. Write the formulas for the first four members of this series: Explain. MOLECULAR FORMULA Ethyne STRUCTURAL FORMULA Ethyne Butyne Propyne Butyne Propyne Pentyne Pentyne 7. Complete the Table. Name of Series Name endings of Members General Formula for Series Bonding in the Carbon Chain Alkane Alkene Alkyne 1. Do you think that there can be a homologous series of alcohols containing two OH groups? Explain. 2. What would be the general formula for a homologous series in which a bromine atom has been substituted for one hydrogen atom in Alkane compounds? NAMING HYDROCARBONS The name for a hydrocarbon generally consists of two parts. The first part indicates the number of carbon atoms in the chain: 1 2 3 4 5 C atom C atoms C atoms C atoms C atoms meth eth prop but pent 6 C atoms 7 C atoms 8 C atoms 9 C atoms 10 C atoms hex hept oct non dec The second part of the name of a hydrocarbon is the same as that of its series. When you know the series to which a hydrocarbon belongs, you have other information available: Series Name Ending General Formula Bonding In C Chain Alkane ane CnH 2n+2 single bonds only Alkene ene CnH 2n one double bond Alkyne yne CnH 2n-2 one triple bond You will use the above information as you answer the questions in this Exercise. 1. How many carbon atoms are in each hydrocarbon? (a) methane (f) hexane (k) decane (b) ethane (g) ethyne (l) butyne (c) ethane (h) propane (m) butene (d) pentane (i) heptane (n) propyne (e) propene (j) octene (o) butane 2. For each compound listed below, underline the name ending, then fill in the blanks with the indicated information: COMPOUND methane butene propyne pentane octane NUMBER OF C ATOMS SERIES TO WHICH IT BELONGS GENERAL FORMULA OF THE SERIES COMPOUND NUMBER OF C ATOMS SERIES TO WHICH IT BELONGS GENERAL FORMULA OF THE SERIES heptene propene butyne decane nonane heptane ethyne hexyne ethene propane 3. Name each of the formulas by first writing down the carbon-count “prefix,” then add the ending indicating the series to which the compound belongs: C2H2 C2H4 C5H12 C3H4 C3H8 C4H6 C2H2 C6H12 CH4 C8H18 C3H6 C10H18 C7H12 C2H6 C5H10 4. Write the structural formula for each of the following: (a) propane (d) butene (b) ethyne (e) propene (c) pentyne (f) butyne (g) methane (j) ethane (h) ethane (k) propyne (i) pentane (l) pentene 5. Name the compound represented by: H (a) H—C ≡ C—H H H H H │ │ │ │ (c) H―C―C―C―C―H │ │ │ │ H H H H H H H H │ │ │ │ (e) H―C―C―C―C═ C ― H │ │ │ │ H H H H (b) H H │ │ C = C—C―H │ H H H │ (d) H―C―H │ H (a) (b) (c) (d) (e) ISOMERS Two builders can use the same amount of materials but construct two houses with different structures. Chemists can take the same amounts of the same elements and bond them together in different arrangements. The different arrangements produce compounds that have completely different properties. Molecules that have the same number of atoms of each element but different arrangements of atoms are called isomers. CHEMICAL HIDE AND SEEK Compounds are classified according to the functional group or groups that are present in their molecular structure. Some classes of compounds and their functional groups are: Alcohol —0—H Acid —C—O—H O H Amine —N H Aldehyde ―C―H ║ O O ║ Ketone ―C―C―C― O ║ Ester —C—O Ether —C—O—C— Other compounds are classified according to the bonding between carbon atoms in hydrocarbons: Alkanes ―C—C― Alkenes —C = C— Alkynes —C ≡ C— The object of Chemical Hide and Seek is to find the hidden clues (functional groups or carbon to carbon bonding) and writing the name of the class of compound beside each “formula.” Find and name the functional group in the formulas given and name the compound. H H │ │ 1) H―C―C―H │ │ H H 2) H H │ │ H―C―C―H │ │ H O―H H │ 3) H―C═ O H O H │ ║ │ 4) H―C―C―O―C―H │ │ H H H O H │ ║ │ 5) H―C―C ―C―H │ │ H H H H │ │ 6) H―C―C―N │ │ H H H H H H H │ │ │ 7) H―C――C――C―H │ │ H H H―C―H │ O―H H 8) H H H O │ │ ║ N―C―C―C―O―H │ │ H H H │ 9) O═C―H H H O H │ │ ║ │ 10) H―C―C―C―C―H │ │ │ H H │ H―C―H │ H H O―H H │ │ │ 14) H―C―C―――C―H │ │ │ H H O―H H H H │ │ │ 15) H―C―C―C ≡C―C―H │ │ │ H H H H H H H │ │ │ │ 16) H―O―C―C ―――C―――C―H │ │ │ │ H H H―C―H H │ H 17) 11) H │ H― C―O―H │ H― C―O―H │ H― C―O―H │ H H │ H ― C ―H 12) 13) H │ H― C │ H C═O O H ║ │ H―O―C―C―H │ H 18) H │ O H │ │ H― C―C―H │ │ H H H H H H H │ │ │ │ │ H―C―C―C ―C ═ C―H │ │ │ H H H H H H │ │ │ 19) H―C―C―O ―C―H │ │ │ H H H H O H H H │ ║ │ │ │ 20) H―C―C ―O ―C ― C―C―H │ │ │ │ H H H H