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Worked solutions to student book questions Chapter 9 Compounds of carbon E1. Write the structural formula of the heptane and 2,2,4-trimethylpentane molecules. EA1. E2. What is the name of the straight-chain hydrocarbon that has same molecular formula as 2,2,4-trimethylpentane? EA2. C8H18 octane Q1. Give the meaning of the following terms: a homologous series b structural isomers c structural formula d semistructural formula e saturated f unsaturated A1. a b c d e g Homologous series: A series of organic compounds in which each members differs by a CH2– group from the previous members. Members of a homologous series have similar chemical properties. Structural isomers: Molecules with the same formula but different molecular structures. Structural formula: A formula that represents the three-dimensional arrangement of atoms in a molecules. Semi-structural formula: A formula that shows the sequence of atoms in a molecules without indicating the three dimensional arrangement of the atoms within the molecule. Saturated: Carbon compounds that only contain single bonds between the carbon atoms. Unsaturated: Carbon compound that contain at least one double or triple bond between adjacent carbon atoms. Heinemann Chemistry 2 4th edition Enhanced Copyright © Pearson Australia 2010 (a division of Pearson Australia Group Pty Ltd) 1 Worked solutions to student book questions Chapter 9 Compounds of carbon Q2. Identify the homologous series to which each of the following belongs: a C3H8 b C2H4 c C5H10 d C8H18 e CH3(CH2)5CH3 f CH3CH=CHCH2CH3 A2. a b c d e f alkane alkene alkene alkane alkane alkene Q3. Draw the structural formula of: a ethane b propene c butane d methylbutane e 3-ethyloctane f 2,3-dimethylhexane A3. a ethane b propene c butane Heinemann Chemistry 2 4th edition Enhanced Copyright © Pearson Australia 2010 (a division of Pearson Australia Group Pty Ltd) 2 Worked solutions to student book questions Chapter 9 Compounds of carbon d methylbutane e 3-ethyloctane f 2,3-dimethylhexane Q4. Explain why there is only one compound corresponding to the formula C3H8 while there are over 70 compounds corresponding to the molecular formula C10H22. A4. The number of possible ways of arranging carbon atoms within a molecule increases as the number of carbon atoms increase. Q5. Describe and explain the difference in bonding and structure between alkanes and alkenes. A5. In alkanes, there is a single bond between all the carbon atoms. There is a tetrahedral arrangement of the bonds formed by each carbon atom. Alkenes contain at least one double bond between adjacent carbon atoms. The bonds formed around the doublebonded carbon atoms lie in the same plane. Q6. Why does the alkene homologous series begin with ethene, C2H4, while the alkanes start with methane, CH4? A6. Alkenes have a double bond between two adjacent carbon atoms. Hence the smallest alkene is ethene, CH2=CH2. Heinemann Chemistry 2 4th edition Enhanced Copyright © Pearson Australia 2010 (a division of Pearson Australia Group Pty Ltd) 3 Worked solutions to student book questions Chapter 9 Compounds of carbon Q7. Give the systematic names for: a CH3OH b HCOOH c CH3Cl d CH3NH2 A7. a b c d methanol (1 carbon, hydroxyl, –OH, functional group) methanoic acid (1 carbon, carboxyl (or acid) , –COOH, functional group) chloromethane (1 carbon , chloro, Cl, functional group) methanamine or methylamine (1 carbon, amine, NH2, functional group) Q8. Write the systematic names of: a CH3CH2CH2Cl b CH2ClCH2CH3 c CH3(CH2)3CH2OH d CH3(CH2)3CHOHCH2CH3 e CH3 CH2CH2NH2 A8. a b c d e 1-chloropropane 1-chloropropane pentan-1-ol heptan-3-ol propan-1-amine or 1-propylamine Q9. Write the semistructural formulas of: a 2-hexanol b 1-chloropentane c butan-1-amine d 2-methylhexane e 4-nonanol A9. a b c d e CH3CHOHCH2CH2CH2CH3 CH2CH2CH2CH2CH2Cl CH3CH2CH2CH2NH2 CH3CH(CH3)CH2CH2CH2CH3 CH3CH2CH2CHOHCH2CH2CH2CH2CH3 Heinemann Chemistry 2 4th edition Enhanced Copyright © Pearson Australia 2010 (a division of Pearson Australia Group Pty Ltd) 4 Worked solutions to student book questions Chapter 9 Compounds of carbon Q10. Why don’t we use the names 1-chloroethane or 3-propanol? A10. Since 1-chloroethane and 2-chloroethane are identical, the molecule is simply named chloroethane. In the case of 3-propanol, this molecule is identical to 1-propanol and it is called 1-propanol by convention. (The numbers used are always the smaller values.) Q11. The semi-structural formulas of some organic compounds is given below. For each compound: i identify the homologous series to which it belongs ii give its systematic name. a CH3(CH2)5CH2Cl b CH3(CH2)2CHCl(CH2)2CH3 c CH3CHOH(CH2)4CH3 d CH3(CH2)4COOH e CH3(CH2)2CH(NH2)CH3 f (CH3)2CHCH2CH3 g (CH3)2C=CH2 A11. Formula CH3(CH2)5CH2Cl CH3(CH2)2CHCl(CH2)2CH3 CH3CHOH(CH2)4CH3 CH3(CH2)4COOH CH3(CH2)2CH(NH2)CH3 (CH3)2CHCH2CH3 (CH3)2C=CHCH3 Homologous series chloroalkanes chloroalkanes alkanols carboxylic acids amines alkanes alkenes Name 1-chloroctane 4-chloroheptane 2-heptanol hexanoic acid pentan-2-amine or 2-pentylamine 2-methylbutane 2-methylbut-2-ene Heinemann Chemistry 2 4th edition Enhanced Copyright © Pearson Australia 2010 (a division of Pearson Australia Group Pty Ltd) 5 Worked solutions to student book questions Chapter 9 Compounds of carbon Q12. Draw the structural formula and name one structural isomer that has the molecular formula: a C5H11Cl b C4H9OH c C2H5COOH d C3H7COOH e C5H11NH2 A12. There are a number of possible answers. Some sample answers are provided. a 1-chloropentane or 3-methyl-2-chlorobutane b 1-butanol c propanoic acid d butanoic acid e pentan-1-amine pentan-1-amine or 2-butanol or methyl propanoic acid or pentan-2-amine pentan-2-amine Heinemann Chemistry 2 4th edition Enhanced Copyright © Pearson Australia 2010 (a division of Pearson Australia Group Pty Ltd) 6 Worked solutions to student book questions Chapter 9 Compounds of carbon Chapter review Q13. Give the systematic names for: a CH3(CH2)7CH2Cl b CH3CH2COOH A13. a b 1-chlorononane propanoic acid Q14. Write the semi-structural formulas of: a 2-chloroheptane b butan-2-ol c decane-3-amine d butanoic acid A14. a b c d CH3CHCl(CH2)4CH3 CH3CHOHCH2CH3 CH3CH2CHNH2CH2CH2CH2CH2CH2CH2CH3 or CH3CH2CHNH2(CH2)6CH3 CH3(CH2)2COOH Q15. Draw the structural formulas of: a butan-2-ol b pentanoic acid c 2-chloropentane d propene e hexan-3-amine f octane A15. a Heinemann Chemistry 2 4th edition Enhanced Copyright © Pearson Australia 2010 (a division of Pearson Australia Group Pty Ltd) 7 Worked solutions to student book questions Chapter 9 Compounds of carbon b c d e f Heinemann Chemistry 2 4th edition Enhanced Copyright © Pearson Australia 2010 (a division of Pearson Australia Group Pty Ltd) 8 Worked solutions to student book questions Chapter 9 Compounds of carbon Q16. Write semistructural formulas and systematic names for the following substances: a b c A16. a b c CH3CH2COOH; propanoic acid CH3CHOHCH3; propan-2-ol HCOOH; methanoic acid Q17. Draw and name all possible isomers of: a C3H7Cl b C5H10 (an alkene) c C5H12 Heinemann Chemistry 2 4th edition Enhanced Copyright © Pearson Australia 2010 (a division of Pearson Australia Group Pty Ltd) 9 Worked solutions to student book questions Chapter 9 Compounds of carbon A17. a 1-chloropropane, 2-chloropropane b 1-pentene, 2-pentene, 2-methyl-1-butene, 2-methyl-2-butene Heinemann Chemistry 2 4th edition Enhanced Copyright © Pearson Australia 2010 (a division of Pearson Australia Group Pty Ltd) 10 Worked solutions to student book questions Chapter 9 Compounds of carbon c pentane, 2-methylbutane, 2,2-dimethylpropane Q18. Draw the structural formulas of five isomers of C5H11Cl. A18. Heinemann Chemistry 2 4th edition Enhanced Copyright © Pearson Australia 2010 (a division of Pearson Australia Group Pty Ltd) 11 Worked solutions to student book questions Chapter 9 Compounds of carbon Q19. Table 9.7 gives the molecular masses and boiling points of butane, propan-1-ol and chloroethane. Explain why the boiling points differ even though the compounds have similar molecular masses. Table 9.7 Compound Butane Propan-1-ol Chloroethane Molecular mass 58 60 65 Boiling point (°C) –0.5 97.0 12.5 A19. The differences in boiling points is indicative of the strength of bonds between molecules. There a weak dispersion forces between butane molecules. In chloroethane, the bond between chlorine and carbon is polar and there are dipoledipole bonds between chloroethane molecules resulting in it having a higher boiling point than butane. Hydrogen bonds exist between the propan-1-ol molecules due to the electronegative nature of the oxygen atom. These bonds are stronger than the bonds between chloroalkane molecules and the bonds between butane molecules. Q20. Explain why alkanols such as methanol and ethanol are soluble in water in all proportions whereas the alkanols higher in the homologous series such as 1-octanol are insoluble. A20. Hydrogen bonds form between the polar hydroxy function group in alkanol in alkanol and water molecules. The alkyl group is non polar and does not interact with water molecules. As the size of the alkyl group increases, the solubility of the alkanol in water decreases. Q21. Write an equation for the ionisation of methanoic acid in water. A21. HCOOH(l) + H2O(l) → HCOO–(aq) + H3O+(aq) Heinemann Chemistry 2 4th edition Enhanced Copyright © Pearson Australia 2010 (a division of Pearson Australia Group Pty Ltd) 12 Worked solutions to student book questions Chapter 9 Compounds of carbon Q22. With the aid of a diagram, explain why methylamine is soluble in water. A22. Bonds around the N atom in methylamine are polar due to the highly electronegative nature of the N atom. Methylamine is soluble in water because hydrogen bonds form between methylamine and water molecules. Q23. Why would ethanamine be more soluble in water than butanamine? A23. The highly polar amino functional group can form hydrogen bonds with water molecules but as the non-polar hydrocarbon chain grows longer, as in butanamine, the solubility is reduced. Q24. Write equations for the the reaction between ethanoic acid solution and: a sodium hydroxide solution b solid sodium carbonate c magnesium A24. a b c CH3COOH(aq) + NaOH(aq) → CH3COONa(aq) + H2O(l) 2CH3COOH(aq) + Na2CO3(s) → 2CH3COONa(aq) + CO2(g) +H2O(l) 2CH3COOH(aq) + Mg(s) → (CH3COO)2Mg + H2(g) Heinemann Chemistry 2 4th edition Enhanced Copyright © Pearson Australia 2010 (a division of Pearson Australia Group Pty Ltd) 13 Worked solutions to student book questions Chapter 9 Compounds of carbon Q25. Prepare a poster that summarises the rules for the systematic naming of carbon compounds. A25. The poster should include reference to the following. Alkanes: • The first part of the name indicates the number of carbon atoms. • The last part ends in -ane. • The stem of the name of branched alkanes is derived from longest alkane hydrocarbon chain. The name and number indicating the position of any akyl side chains is then added. Alkenes: • The names of alkenes end in -ene. • The stem of the systematic name of alkenes is based on the longest carbon chain that contains the double bond. • The position of the double bond is indicated by the number of the first carbon atom involved in the double bond. By convention, numbering starts from the end nearest the double bond. The rules for naming of any side chains are similar to those for the alkanes. Functional groups: • Numbers are used to indicate the position of the functional group attached to the carbon chain • Chloroalkanes: the name starts with chloro- followed by the name of the alkane from which it is derived. • Alkanols are named by dropping the ‘e’ at the end of the hydrocarbon name and replacing it with ‘ol’. • Carboxylic acid: The name of carboxylic acids is determined from the total number of carbon atoms in the molecule, and -oic acid is added at the end of the name. • Amines are named by adding -amine to the alkane stem. Q26. Prepare notes for a PowerPoint presentation that outlines the reasons why carbon is able to form so many different compounds. A26. The notes might include. • Carbon forms stable bonds with other carbon atoms, and can form large chains as well as cyclic structures. • Carbon forms single, double or triple bonds with other carbon atoms. • Carbon is able to bond with the atoms of other elements, H, O, N, P, Cl, and with groups of atoms (functional groups). • There are different organic compounds that have the same molecular formula – isomers. Heinemann Chemistry 2 4th edition Enhanced Copyright © Pearson Australia 2010 (a division of Pearson Australia Group Pty Ltd) 14