Workbook – Worked Solutions Chapter 4 – The Periodic Table
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Workbook – Worked Solutions Chapter 4 – The Periodic Table.....................................................75 Chapter 9 – The Mole Concept......................................................76 Chapter 10 – Properties of Gases ...................................................87 Chapter 11 – Stoichiometry ............................................................98 Chapter 13 – Volumetric Analysis: Acid-Base............................111 Chapter 15 – Volumetric Analysis: Oxidation-Reduction .........123 Chapter 16 – Rates of Reaction ....................................................135 Chapter 17 – Chemical Equilibrium............................................137 Chapter 18 – pH and Indicators...................................................144 Chapter 19 – Environmental Chemistry – Water.......................151 Chapter 21 – Fuels and Heats of Reaction...................................156 Chapter 24 – Stoichiometry II ......................................................160 Chemistry Live! – Worked Solutions Workbook Chapter 4 – The Periodic Table W4.2 (b) In 100 atoms of boron there are: 81 atoms of mass 11 = 81 × 11 = 891 19 atoms of mass 10 = 19 × 10 = 190 ––––––––––––––––––––––––––––––––– Total mass of 100 atoms = 1081 Average mass of 1 atom = 10.81 Answer: Relative atomic mass of boron = 10.81 W4.3 In 100 atoms of neon there are 90 atoms of mass 20 = 90 × 20 = 1800 10 atoms of mass 22 = 10 × 22 = 220 ––––––––––––––––––––––––––––––––– Total mass of 100 atoms = 2020 Average mass of 1 atom = 20.2 Answer: Relative atomic mass of neon = 20.2 W4.5 In 100 atoms of nickel there are: 70 atoms of mass 58 = 70 × 58 = 4060 26 atoms of mass 60 = 26 × 60 = 1560 4 atoms of mass 62 = 4 × 62 = 248 –––––––––––––––––––––––––––––––––– Total mass of 100 atoms = 5868 Average mass of 1 atom = 58.68 Answer: Relative atomic mass of nickel = 58.68 75 Chemistry Live! – Worked Solutions Workbook Chapter 9 – The Mole Concept W9.1 (a) 1 mole of Li atoms = 7 g (b) 1 mole of Na atoms = 23 g (c) 1 mole of Ca atoms = 40 g (d) 1 mole of Fe atoms = 56 g (e) 1 mole of Ag atoms = 108 g (f) 1 mole of Pb atoms = 207 g W9.2 (a) 1 mole of Cl atoms = 35.5 g 10 moles of Cl atoms = 35.5 × 10 = 355 g (b) 1 mole of Br atoms 1 mole of Br2 molecules 0.125 moles of Br2 molecules (c) 1 mole of H2 O = (1 × 2) + 16 = 18 g 0.25 mole of H2 O = 18 × 0.25 = 4.5 g (d) 1 mole of S atoms 1 mole of S8 molecules 0.5 moles of S8 molecules (e) 1 mole of HNO3 molecules = 1 + 14 + (16 × 3) = 63 g 0.5 moles of HNO3 molecules = 63 × 0.5 = 31.5 g (f) 1 mole of SO4 2- ions 0.5 moles of SO4 2- ions (g) 1 mole of O atoms = 16 g 1 mole of O2 molecules = 16 × 2 = 32 g 0.05 mole of O2 molecules = 32 × 0.05 = 1.6 g 76 = 80 g = 80 × 2 = 160 g = 160 × 0.125 = 20 g = 32 g = 32 × 8 = 256 g = 256 × 0.5 = 128 g = 32 + (16 × 4) = 96 g = 96 × 0.5 = 48 g Chemistry Live! – Worked Solutions W9.3 (a) Relative Molecular Mass NaOH i.e 1 mole of NaOH ⇒ 4 moles of NaOH = 23 + 16 + 1 = 40 = 40 g = 40 × 4 = 160 g = 40 + (2 × 35.5) = 40 + 71 = 111 = 111g = 111 × 0.5 = 55.5 g (b) Relative Molecular Mass CaCl2 i.e 1 mole of CaCl2 ⇒ 0.5 moles of CaCl2 (c) Relative Molecular Mass Cl2 i.e. 1 mole of Cl2 ⇒ 2 moles of Cl2 (d) Relative Molecular Mass MgO i.e. 1 mole of MgO ⇒ 0.05 mole of MgO (e) Relative Molecular Mass Fe2 O3 i.e. 1 mole of Fe2 O3 ⇒ 3 moles of Fe2 O3 (f) Relative Molecular Mass C2 H6 i.e. 1 mole of C2 H6 ⇒ 0.1 mole C2 H6 (g) Relative Molecular Mass CaCO3 = 40 + 12 + (3 × 16) = 40 + 12 + 48 = 100 i.e. 1 mole of CaCO3 = 100 g ⇒ 0.6 mole of CaCO3 = 100 × 0.6 = 60 g (h) Relative Molecular Mass NaCl = 23 + 35.5 = 58.5 i.e. 1 mole of NaCl = 58.5 g ⇒ 0.3 moles of NaCl = 58.5 × 0.3 = 17.55 g (i) Relative Molecular Mass H2 O = (2 × 1) + 16 = 18 i.e. 1 mole of H2 O = 18 g ⇒ 4 moles of H2 O = 18 × 4 = 72 g = 2 × 35.5 = 71 = 71g = 71 × 2 = 142 g = 24 + 16 = 40 = 40 g = 40 × 0.05 =2g = (2 × 56) + (3 × 16) = 112 + 48 = 160 = 160 g = 160 × 3 = 480 g = (2 × 12) + (6 × 1) = 24 + 6 = 30 = 30 g = 30 × 0.1 =3g 77 Chemistry Live! – Worked Solutions (j) Relative Molecular Mass Ca(NO3 )2 i.e.1 mole of Ca(NO3 )2 ⇒ 0.075 moles of Ca (NO3 )2 = 40 + (14 × 2) + (16 × 6) = 40 + 28 + 96 = 164 = 164 g = 164 × 0.075 = 12.3 g (k) Relative Molecular Mass (NH4 )2 SO4 = (2 × 14) + (8 × 1) + 32 + (4 × 16) = 28 + 8 + 32 + 64 = 132 i.e. 1 mole of (NH4 )2 SO4 = 132 g ⇒ 0.02 moles of (NH4 )2 SO4 = 132 × 0.02 = 2.64 g (l) Relative Molecular Mass CuO i.e. 1 mole of CuO ⇒ 0.25 moles of CuO (m) Relative Molecular Mass SO3 i.e. 1 mole of SO3 ⇒ 0.1 moles of SO3 (n) Relative Molecular Mass Cu2 O = (63.5 × 2) + 16 = 127 + 16 = 143 i.e.1 mole of Cu2 O = 143 g ⇒ 0.25 moles of Cu2 O = 143 × 0.25 = 35.75 g (o) Relative Molecular Mass (NH4 )2 CO3 = (2 × 14) + (8 × 1) + 12 + (3 × 16) = 28 + 8 + 12 + 48 = 96 i.e. 1 mole of (NH4 )2 CO3 = 96 g ⇒ 3 moles of (NH4 )2 CO3 = 96 × 3 = 288 g (p) Relative Molecular Mass Br2 i.e. 1 mole of Br2 ⇒ 0.25 moles of Br2 (q) Relative Molecular Mass H2 SO4 i.e. 1 mole of H2 SO4 ⇒ 0.8 moles of H2 SO4 78 = 63.5 + 16 = 79.5 = 79.5 g = 79.5 × 0.25 = 19.875 g = 32 + (3 × 16) = 32 + 48 = 80 = 80 g = 0.1 × 80 =8g = 2 × 80 = 160 = 160 g = 160 × 0.25 = 40 g = (2 × 1) + 32 + (4 × 16) = 2 + 32 + 64 = 98 = 98 g = 98 × 0.8 = 78.4 g Chemistry Live! – Worked Solutions (r) Relative Molecular Mass FeCl2 i.e 1 mole of FeCl2 ⇒ 4 moles of FeCl2 (s) Relative Molecular Mass C12 H26 i.e. 1 mole of C12 H26 ⇒ 1 × 10-4 moles of C12 H26 = 56 + (2 × 35.5) = 56 + 71 = 127 = 127 g = 127 × 4 = 508 g = (12 × 12) + (26 × 1) = 144 + 26 = 170 = 170 g = 170 × 1 × 10-4 = 0.017 g W9.4 (a) Relative Molecular Mass CH4 = 12 + (4 × 1) = 12 + 4 = 16 Mass 80 Number of moles of CH4 = –––––––––––––––– = ––– = 5 Rel molecular mass 16 (b) Relative Molecular Mass SO2 = 32 + (2 × 16) = 32 + 32 = 64 Mass 288 Number of moles of SO2 = –––––––––––––––– = –––– = 4.5 Rel molecular mass 64 (c) Relative Molecular Mass H2 O = (2 × 1) + 16 = 2 + 16 = 18 Mass 0.32 Number of moles of H2 O = ––––––––––––––––– = ––––– = 0.0178 Rel molecular mass 18 (d) Relative Molecular Mass H2 SO4 = (2 × 1) + 32 + (4 × 16) = 2 + 32 + 64 = 98 Mass 441 Number of moles of H2 SO4 = –––––––––––––––– = ––––– = 4.5 Rel molecular mass 98 (e) Relative Molecular Mass NH4 NO3 = 14 + (4 × 1) + 14 + (3 × 16) = 14 + 4 + 14 + 48 = 80 Mass 10 Number of moles of NH4 NO3 = –––––––––––––––– = ––– = 0.125 Rel molecular mass 80 79 Chemistry Live! – Worked Solutions (f) Relative Molecular Mass C6 H12 O6 = (6 × 12) + (12 × 1) + (6 × 16) = 72 + 12 + 96 = 180 Mass 18 Number of moles of C6 H12 O6 = ––––––––––––––––– = –––– = 0.1 Rel molecular mass 180 W9.5 (a) Relative Molecular Mass CaCO3 = 40 + 12 + (3 × 16) = 40 + 12 + 48 = 100 Mass 500 Number of moles of CaCO3 = ––––––––––––––––– = –––– = 5 Rel. molecular mass 100 (b) Relative Molecular Mass NaCl = 23 + 35.5 = 58.5 Mass 351 Number of moles of NaCl = ––––––––––––––––– = –––– = 6 Rel. molecular mass 58.5 (c) Relative Molecular Mass NaOH = 23 + 16 + 1 = 40 Mass 4 Number of moles of NaOH = ––––––––––––––––– = ––– = 0.1 Rel molecular mass 40 (d) Relative Molecular Mass KNO3 = 39 + 14 + (3 × 16) = 39 + 14 + 48 = 101 Mass 25.25 Number of moles of KNO3 = ––––––––––––––––– = –––––– = 0.25 Rel molecular mass 101 (e) Relative Molecular Mass CuSO4 .5H2 O = 63.5 + 32 + (4 × 16) + (5 × 18) = 63.5 + 32 + 64 + 90 = 249.5 Mass 24.95 Number of moles of CuSO4 .5H2 O = ––––––––––––––––– = –––––– = 0.1 Rel molecular mass 249.5 80 Chemistry Live! – Worked Solutions W9.6 (a) 1 mole of H2 O contains 6 × 1023 molecules 0.25 moles of H2 O contain 0.25 × 6 × 1023 molecules = 1.5 × 1023 molecules (b) 1 mole of CH4 contains 6 × 1023 molecules 7.2 moles of CH4 contain 7.2 × 6 × 1023 molecules = 4.32 × 1024 molecules (c) 1 mole of CO2 contains 6 × 1023 molecules 8 moles of CO2 contain 8 × 6 × 1023 molecules = 4.8 × 1024 molecules (d) 1 mole of H2 SO4 contains 6 × 1023 molecules 0.001 mole of H2 SO4 contains 0.001 × 6 × 1023 molecules = 6 × 1020 molecules (e) 1 mole of NH3 contains 6 × 1023 molecules 5 × 10-3 mole of NH3 contains 5 × 10-3 × 6 × 1023 = 3 × 10 21 molecules W9.7 (a) Relative molecular mass O2 = 2 × 16 = 32 1 mole of O2 contains 6 × 1023 molecules i.e. 32 g of O2 contain 6 × 1023 molecules 6 × 1023 1 g of O2 contains ––––––– molecules 32 6 × 1023 × 0.4 0.4 g of O2 contain ––––––––––– molecules 32 = 7.5 × 1021 molecules (b) Relative molecular mass Cl2 = 2 × 35.5 = 71 1 mole of Cl2 contains 6 × 1023 molecules i.e. 71 g of Cl2 contain 6 × 1023 molecules 6 × 1023 1 g of Cl2 contains ––––––––––– molecules 71 6 × 1023 × 142 142 g of Cl2 contain ––––––––––––– molecules 71 = 1.2 × 1024 molecules 81 Chemistry Live! – Worked Solutions (c) Relative molecular mass CO2 = 12 + (2 × 16) = 44 1 mole of CO2 contains 6 × 1023 molecules i.e. 44g of CO2 contain 6 × 1023 molecules 6 × 1023 1 g of CO2 contains ––––––––– molecules 44 40 × 6 × 1023 40 g of CO2 contain –––––––––––– molecules 44 = 5.45 × 1023 molecules (d) Relative molecular mass CH4 = 12 + (4 × 1) = 16 1 mole of CH4 contains 6 × 1023 molecules i.e.16 g of CH4 contain 6 × 1023 molecules 6 × 1023 1 g of CH4 contains –––––––– molecules 16 50 × 6 × 1023 50 g of CH4 contain –––––––––––– molecules 16 = 1.875 × 1024 molecules W9.8 (a) Relative atomic mass Al = 27 i.e. 1 mole of Al = 27 g ⇒ 6 × 1023 atoms of Al = 27 g 27 1 atom of Al = –––––––– g 6 × 1023 2 × 10 25 27 × 2 × 1025 atoms of Al = –––––––––––– g 6 × 1023 = 900 g 82 Chemistry Live! – Worked Solutions (b) Relative atomic mass Mg = 24 i.e. 1 mole of Mg = 24 g ⇒ 6 × 1023 atoms of Mg = 24 g 24 1 atom of Mg = –––––––– g 6 × 1023 24 × 3 × 1021 3 × 1021 atoms of Al = –––––––––––– g 6 × 1023 = 0.12 g (c) Relative atomic mass Ag = 108 i.e. 1 mole of Ag = 108 g ⇒ 6 × 1023 atoms of Ag = 108 g 108 1 atom of Ag = ––––––– g 6 × 1023 108 × 1.15 × 1012 1.15 × 1012 atoms of Ag = –––––––––––––––– g 6 × 1023 = 2.07 × 10-10 g (d) Relative molecular mass H2 O = (1 × 2) + 16 = 2 + 16 = 18 i.e. 1 mole of H2 O = 18 g ⇒ 6 × 1023 molecules of H2 O = 18 g 18 1 molecule of H2 O = –––––––– g 6 × 1023 18 × 1.5 × 1025 1.5 × 1025 molecules of H2 O = ––––––––––––– g 6 × 1023 = 450 g 83 Chemistry Live! – Worked Solutions (e) Relative molecular mass CO2 = 12 + (2 × 16) = 12 + 32 = 44 i.e. 1 mole of CO2 = 44 g ⇒ 6 × 1023 molecules of CO2 = 44 g 44 1 molecule of CO2 = ––––––– g 6 × 1023 8 × 10 21 44 × 8 × 1021 molecules of CO2 = ––––––––––– g 6 × 1023 = 0.5867 g Revision Question W9.9 (b) 1 mole of Al2 (SO4 )3 contains 2 moles of Al3+ ⇒ 3 moles of Al2 (SO4 )3 contain 2 × 3 = 6 moles Al3+ (c) Relative Molecular Mass Na2 SO3 = (2 × 23) + 32 + (3 × 16) = 46 + 32 + 48 = 126 1 mole of Na2 SO3 contains 6 × 1023 SO3 2- ions i.e. 126 g of Na2 SO3 contain 6 × 1023 SO3 2- ions 6 × 1023 1 g of Na2 SO3 contains –––––––– SO3 2- ions 126 2.1 × 6 × 1023 2.1 g of Na2 SO3 contain –––––––––––– SO3 2- ions 126 = 1 × 1022 SO3 2- ions (d) 1 mole of Mg contain 6 × 1023 atoms i.e. 24 g of Mg contain 6 × 1023 atoms 6 × 1023 1 g of Mg contains –––––––– atoms 24 0.36 × 6 × 1023 0.36 g Mg contains –––––––––––––– atoms 24 = 9 × 1021 atoms 84 Chemistry Live! – Worked Solutions (e) 1 mole of Ca contains 6 × 1023 atoms of Ca i.e. 40g of Ca contain 6 × 1023 atoms of Ca 6 × 10 23 1g Ca contains –––––––– atoms of Ca 40 8 × 6 × 1023 8g Ca contain ––––––––––– atoms of Ca 40 = 1.2 × 1023 atoms of Ca 6 × 1023 atoms of Mg = 24g 24 1 atom of Mg = –––––––– g 6 × 1023 24 × 1.2 × 1023 1.2 × 1023 atoms of Mg = –––––––––––– g 6 × 1023 = 4.8g (f) Mass 0.2 Number of moles of Mg = ––––––––––––––––––– = –––– = 8.33 × 10–3 mole Relative Atomic Mass 24 (g) Mass 7 Number of moles of Fe = –––––––––––––––––– = ––– = 0.125 mole Relative Atomic Mass 56 0.125 mole of Mg will contain the same number of atoms as 0.125 mole of Fe. 1 mole of Mg = 24 g ⇒ 0.125 mole Mg = 0.125 × 24 = 3 g (h) Relative molecular mass HNO3 = 1 + 14 + (3 × 16) = 63 Mass 6.3 Number of moles of HNO3 = –––––––––––––––– = –––– = 0.1 mole Rel molecular mass 63 1 mole of HNO3 contains 3 moles of O atoms ⇒ 0.1 mole of HNO3 contain 3 × 0.1 = 0.3 mole of O atoms. 85 Chemistry Live! – Worked Solutions (i) Relative molecular mass CH4 = 12 + (4 × 1) = 16 Mass 6.4 Number of moles of CH4 = ––––––––––––––––– = –––– = 0.4 Rel molecular mass 16 1 mole of CH4 contains 4 moles of H atoms ⇒ 0.4 mole of CH4 contain 4 × 0.4 = 1.6 moles of H atoms (j) Mass 22 Number of moles of Cu = –––––––––––––––––– = ––––– = 0.346 Relative Atomic Mass 63.5 Mass 46 Number of moles of Al = –––––––––––––––––– = –––– = 1.704 Relative Atomic Mass 27 Mass 2.6 Number of moles of Fe = –––––––––––––––––– = –––– = 0.046 Relative Atomic Mass 56 (k) Mass 39 Number of moles of K = –––––––––––––––––– = ––– = 1 Relative Atomic Mass 39 1 mole of K will contain the same number of atoms as 1 mole of C. Mass of 1 mole of C = 12 g - (l) 1 mole of Mg(NO3 )2 contains 2 moles of NO3 ions ⇒ 2 moles of Mg(NO3 )2 contain 2 × 2 = 4 moles of NO3 - ions (m) Relative molecular mass CO2 = 12 + (2 × 16) = 44 Mass 22 Number of moles of CO2 = –––––––––––––––– = ––– = 0.5 Rel molecular mass 44 0.5 mole of CO2 will contain the same number of molecules as 0.5 mole of H2 O. 1 mole of water ⇒ 0.5 mole of water = 0.5 × 18 = 9 g 86 = 18 g Chemistry Live! – Worked Solutions Workbook Chapter 10 - Properties of Gases W10.1 Given V1 = 30 cm3 p1 = 975 kPa T1 = 25 °C + 273 = 298 K p1 V1 ––––– T1 s.t.p. V2 = ? p2 =100 kPa T2 = 273 K p2 V2 ––––– T2 = 975 × 30 –––––––– = 298 100 × V2 –––––––– 273 ⇒ V2 975 × 30 × 273 = –––––––––––––– 298 × 100 = 267.96 cm3 W10.2 Given V1 = 2.5 L p1 = 300 kPa T1 = T2 p1 V1 s.t.p. V2 = ? p2 =100 kPa p2 V2 ––––– = ––––– T1 T2 300 × 2.5 = 100 × V2 300 × 2.5 ⇒ V2 = –––––––––– 100 = 7.5 L 87 Chemistry Live! – Worked Solutions W10.3 Old V1 = 1.2 m3 p1 = 101 kPa T1 = 5 °C + 273 = 278 K New V2 = ? p2 = 108 kPa T2 = 30 °C + 273 = 303 K . p1 V1 p2 V2 ––––– = ––––– T1 T2 101 × 1.2 –––––––––– 278 108 × V2 = –––––––––– 303 101 × 1.2 × 303 ⇒ V2 = –––––––––––––––– 278 × 108 = 1.22 m3 W10.5 (a) Rel molecular mass O2 = 2 × 16 = 32 i.e. 1 mole of O2 = 32 g 32 g of O2 occupies 22.4 L at s.t.p 22.4 1 g of O2 occupies ––––– L 32 22.4 × 10 ⇒10 g of O2 occupies –––––––––– L 32 =7L (b) Rel molecular mass CO2 = 12 + (2 × 16) = 12 + 32 = 44 i.e. 1 mole of CO2 = 44 g 44 g of CO2 occupies 22.4 L at s.t.p 22.4 1 g of CO2 occupies ––––– L 44 22.4 × 12 ⇒12 g of CO2 occupies –––––––––– L 44 = 6.11 L 88 Chemistry Live! – Worked Solutions (c) Rel molecular mass NH3 = 14 + (3 × 1) = 14 + 3 = 17 i.e. 1 mole of NH3 = 17 g 17 g of NH3 occupies 22.4 L at s.t.p 22.4 1 g of NH3 occupies –––––– L 17 22.4 × 8 ⇒ 8 g of NH3 occupies –––––––––– L 17 = 10. 54 L (d) Rel molecular mass CO = 12 + 16 = 28 i.e. 1 mole of CO = 28 g 28 g of CO occupies 22.4 L at s.t.p 22.4 1 g of CO occupies –––––– L 28 22.4 × 25 ⇒ 25 g of CO occupies –––––––––– L 28 = 20 L (e) Rel molecular mass NO2 = 14 + (2 × 16) = 14 + 32 = 46 i.e. 1 mole of NO2 = 46 g 46 g of NO2 occupies 22.4 L at s.t.p 22.4 1 g of NO2 occupies –––––– L 46 22.4 × 12 ⇒ 12 g of NO2 occupies –––––––––– L 46 = 5.84 L 89 Chemistry Live! – Worked Solutions Rel molecular mass H2 S = (2 × 1) + 32 = 2 + 32 = 34 i.e. 1 mole of H2 S = 34 g 34 g of H2 S occupies 22.4 L at s.t.p (f) 22.4 1 g of H2 S occupies ––––– L 34 22.4 × 13 ⇒ 13 g of H2 S occupies –––––––––– L 34 = 8.56 L W10.6 p = 200 kPa = 200 × 103 Pa V = 100 cm3 = 100 × 10-6 m3 n=? R = 8.31 J mol-1 K-1 T = 30 °C + 273 = 303 K pV = nRT pV n = –––– RT 200 × 103 × 100 × 10-6 = –––––––––––––––––––––– 8.31 × 303 = 7.94 × 10-3 moles 90 Chemistry Live! – Worked Solutions W10.7 p = 101.325 kPa = 101325 Pa V = 512 cm3 = 512 × 10-6 m3 n=? R = 8.31 J mol-1 K-1 T = 20 °C + 273 = 293 K Mass of liquid = 1.236 g pV = nRT pV n = –––– RT 101325 × 512 × 10-6 = ––––––––––––––––––––– 8.31 × 293 = 0.0213 mole i.e. 0.0213 mole = 1.236 g 1.236 1 mole of liquid = –––––– 0.0213 = 58.03 i.e. Relative molecular mass of liquid = 58 (to nearest whole number) 91 Chemistry Live! – Worked Solutions W10.8 p = 101.3 kPa = 101300 Pa V = 200 cm3 = 200 × 10-6 m3 n=? R= 8.31 J mol-1 K-1 T= 25 °C + 273 = 298 K Mass of liquid = 1.0 g pV = nRT pV n = ––– RT 101300 × 200 × 10-6 = –––––––––––––––––––– 8.31 × 298 = 8.18 × 10-3 mole i.e. 8.18 × 10-3 mole = 1.0 g 1.0 1 mole of liquid = –––––––––––– 8.18 × 10-3 = 122.25 i.e. Relative molecular mass of gas = 122 (to nearest whole number) 92 Chemistry Live! – Worked Solutions W10.9 Laboratory V1 = 328 cm3 p1 = 9.8 × 104 Pa T1 = 100 °C + 273 = 373 K p 1 V1 s.t.p. V2 = ? p2 = 1 × 105 Pa T2 = 273 K p2 V2 = ––––– ––––– T1 T2 9.8 × 104 × 328 1 × 105 × V2 –––––––––––––––– 373 = ––––––––––––––– 273 9.8 × 104 × 328 × 273 ⇒ V2 = ––––––––––––––––––––––– 373 × 1 × 105 = 235.26 cm3 Mass of condensed liquid = 102.84 – 101.41 = 1.43 g At s.t.p. 235.26 cm3 of the vapour have a mass of 1.43g 1.43 3 1 cm of the vapour has a mass of ––––––– g 235.26 22,400 × 1.43 ⇒ 22,400 cm of the vapour have a mass of ––––––––––––––– 235.26 3 = 136.16 g i.e Relative molecular mass = 136 (to nearest whole number) 93 Chemistry Live! – Worked Solutions W10.10 p = 1.02 × 105 Nm-2 V = 67 – 6 = 61 cm3 = 61 × 10-6 m3 n=? R = 8.31 J mol-1 K-1 T = 100 °C + 273 = 373 K Mass of liquid injected = 13.179 – 12.910 = 0.269 g pV = nRT pV n = ––– RT 1.02 × 105 × 61 × 10-6 = ––––––––––––––––––––––– 8.31 × 373 = 2.01 × 10-3 mole i.e. 2.01 × 10-3 mole = 0.269 g 0.269 1 mole of liquid = –––––––––––– 2.01 × 10-3 = 133.83 i.e. Relative molecular mass of liquid = 134 (to nearest whole number) 94 Chemistry Live! – Worked Solutions W10.11 p = 1 × 105 Nm-2 V = 4.98 × 10-3 m3 n=? R = 8.31 J mol-1 K-1 T = 27 °C + 273 = 300 K pV = nRT pV n = –––– RT 1 × 105 × 4.98 × 10-3 = –––––––––––––––––––––– 8.31 × 300 = 0.20 moles i.e. 0.20 moles = 5.6 g 5.6 1 mole of gas = ––––– 0.2 = 28 i.e. Relative molecular mass of diatomic gas = 28 ⇒ gas = N2 The element is nitrogen. 95 Chemistry Live! – Worked Solutions W10.12 (iii) p = 1 × 105 Nm-2 V = 3.15 × 10-4 m3 n=? R = 8.31 J mol-1 K-1 T = 300 K pV = nRT pV n = ––– R 1 × 105 × 3.15 × 10-4 = –––––––––––––––––––––– 8.31 × 300 = 1.26 × 10-2 mole i.e. 1.26 × 10-2 mole = 1.1 g 1.1 1 mole of gas = ––––––––––– 1.26 × 10-2 = 87.30 i.e. Relative molecular mass of gas = 87.30 W10.13 (b) s.t.p V1 = 500 cm3 p1 = 1.01 × 105 Nm-2 T1 = 273 K p 1 V1 new V2 = ? p2 = 2.02 × 105 Nm-2 T2 = 819 K p2 V2 = ––––– ––––– T1 T2 1.01 × 105 × 500 2.02 × 105 × V2 ––––––––––––––––– = ––––––––––––––– 273 819 1.01 × 105 × 500 × 819 ⇒ V2 = –––––––––––––––––––––––– 2.02 × 105 × 273 = 750 cm3 96 Chemistry Live! – Worked Solutions (c) Rel molecular mass N2 = 2 × 14 = 28 i.e. 1 mole of N2 = 28 g 28 g of N2 occupy 22.4 L at s.t.p. 22.4 ⇒1 g of N2 occupies ––––– L = 0.8 L 28 (e) Mass Density = ––––––––– Volume 2.5 Mass of one mole Mass of one mole = –––––––––––––––––––– = ––––––––––––––––––– Molar volume 22.4 ⇒ Mass of one mole = 22.4 × 2.5 = 56 g i.e. Relative molecular mass of gas = 56 W10.14 (vi) p = 1.0 × 105 Nm-2 V = 168 cm3 = 168 × 10-6 m3 n=? R = 8.4 N m mol-1 K-1 T = 300 K pV = nRT pV n = ––––– RT 1.0 × 105 × 168 × 10-6 = –––––––––––––––––––––– 8.4 × 300 = 6.67 × 10-3 moles i.e. 6.67 × 10-3 moles = 0.3 g 0.3 1 mole of liquid = –––––––––––– 6.67 × 10-3 = 44.98 i.e. Relative molecular mass of liquid = 44.98 97 Chemistry Live! – Worked Solutions Workbook Chapter 11 - Stoichiometry W11.1 (a) Relative molecular mass Na2 CO3 .10H2 O = (23 × 2) + 12 + (16 × 3) + 10 [(1 × 2) + 16] = 46 + 12 + 48 + (10 × 18) = 46 +12 + 48 + 180 = 286 180 % H2 O = ––––– × 100 = 62.94 % 286 (b) Relative molecular mass MgSO4 .7H2 O = 24 + 32 + (16 × 4) + 7 [(1 × 2) + 16] = 24 + 32 + 64 + (7 × 18) = 24 + 32 + 64 + 126 = 246 126 % H2 O = ––––– × 100 = 51.22 % 246 W11.2 Relative molecular mass Fe2 O3 = (56 × 2) + (16 × 3) = 112 + 48 = 160 112 % Fe = ––––– × 100 = 70 % 160 Relative molecular mass Fe3 O4 = (56 × 3) + (16 × 4) = 168 + 64 = 232 168 % Fe = ––––– × 100 = 72.41% 232 Magnitite Fe3 O4 contains the higher % of Fe. W11.3 Element Percentage Percentage ––––––––––––––– Carbon Hydrogen Oxygen 98 Rel. At. Mass 64.9 64.9 –––––– = 5.41 12 13.5 13.5 ––––– = 13.5 1 21.6 21.6 –––––– = 1.35 16 i.e. Empirical formula = C4 H10 O Simplest ratio (divide by 1.35) 5.41 ––––– =4 1.35 13.5 ––––– = 10 1.35 1.35 ––––– 1.35 =1 Chemistry Live! – Worked Solutions Molecular Formula = empirical formula × n 74 = (C 4 H10 O) × n 74 = [(12 × 4) + (1 × 10) + 16] n 74 = (48 + 10 + 16) n 74 = 74 n n=1 ⇒ Molecular Formula = (C 4 H10 O) × 1 = C4 H10 O i.e. Molecular Formula = empirical formula = C4 H10 O W11.4 Element Percentage Percentage ––––––––––––––– Carbon 26.7 Hydrogen Oxygen 2.2 71.1 Rel. At. Mass 26.7 ––––– = 2.23 12 2.2 –––– = 2.2 1 71.1 ––––– = 4.44 16 Simplest ratio (divide by 2.2) 2.23 ––––– =1 2.2 2.2 ––––– =1 2.2 4.44 ––––– =2 2.2 i.e. Empirical formula = CHO2 Molecular Formula = empirical formula × n 90 = (CHO 2 ) × n 90 = [12 + 1 + (16 × 2)] n 90 = (12 + 1 + 32) n 90 = 45n n=2 ⇒ Molecular Formula = (CHO 2 ) × 2 = C2 H2 O4 i.e. Molecular Formula = C2 H2 O4 99 Chemistry Live! – Worked Solutions W11.5 Element Percentage Percentage ––––––––––––––– Carbon 64.8 Hydrogen Oxygen 13.6 21.6 Rel. At. Mass 64.8 ––––– = 5.4 12 13.6 ––––– = 13.6 1 21.6 –––––– = 1.35 16 i.e. Empirical formula = C4 H10 O Molecular Formula = empirical formula × n 74 = (C 4 H10 O) × n 74 = [(12 × 4) + (1 × 10) + 16] n 74 = (48 + 10 + 16) n 74 = 74n n=1 ⇒ Molecular Formula = (C 4 H10 O) × 1 = C4 H10 O i.e. Molecular Formula = C4 H10 O 100 Simplest ratio (divide by 1.35) 5.4 –––––– =4 1.35 13.6 ––––– = 10 1.35 1.35 ––––– 1.35 =1 Chemistry Live! – Worked Solutions W11.6 Lead + iodine → lead iodide 2.07 g 4.61 g mass of lead = 2.07 g mass of lead iodide = 4.61 g ⇒ mass of iodine in lead iodide = 4.61 – 2.07 = 2.54 g mass number of moles of Pb in lead iodide = ––––––––––––––––– Rel. atomic mass 2.07 = –––––– = 0.01 207 mass number of moles of I in lead iodide = ––––––––––––––––– Rel. atomic mass 2.54 = ––––– = 0.02 127 Ratio of Pb : I = 0.01 : 0.02 = 1 : 2 ⇒ Empirical Formula = PbI2 101 Chemistry Live! – Worked Solutions W11.7 CuSO4 .xH2 O → CuSO4 + x H2 O 3.94 g 2.52 g mass of CuSO4 = 2.52 g mass of CuSO4 .xH2 O = 3.94 g mass of H2 O in CuSO4 .xH2 O = 3.94 – 2.52 = 1.42 g Rel. mol. mass CuSO4 = 63.5 + 32 + (16 × 4) = 63.5 + 32 + 64 = 159.5 Rel. mol. mass H2 O = (1 × 2) + 16 = 18 mass number of moles of CuSO4 in CuSO4 .xH2 O = –––––––––––––– Rel. mol. mass 2.52 = –––––– = 0.0158 159.5 mass number of moles of water in CuSO4 .xH2 O = –––––––––––––––– Rel. mol. mass 1.42 = ––––– = 0.0789 18 Ratio of CuSO4 : H2 O = 0.0158 : 0.0789 = 1 : 5 i.e. CuSO4 .5H2 O is the formula of the hydrated salt. 102 Chemistry Live! – Worked Solutions W11.8 M + oxygen → M2 O 9.76 g 20.9 g mass of M = 9.76 g mass of M2 O = 20.9 g mass of O2 = 20.9 – 9.76 = 11.14 g mass number of moles of O2 = ––––––––––––––– Rel. mol. mass 11.14 = ––––––– = 0.6963 16 Since in the compound M2 O the ratio M : O = 2 : 1 ⇒ number of moles of metal = 0.6963 × 2 = 1.3926 i.e. 1.3926 moles of M = 9.76 g 9.76 1 mole of M = –––––––– 1.3926 = 7.01 ≈ 7 i.e. Relative atomic mass of M = 7 W11.9 Rel. mol. mass Mg3 N2 = (24 × 3) + (14 × 2) = 72 + 28 = 100 i.e. 3Mg + N2 → 3Mg → 3 moles → 3 (24) g → 72 g Mg → 1 g Mg Mg3 N2 Mg3 N2 (shortened version of equation) 1 mole 100 g 100 g 100 → –––– g Mg3 N2 72 33 × 100 33 g Mg → –––––––– g Mg3 N2 72 = 45.83 g Mg3 N2 103 Chemistry Live! – Worked Solutions W11.10 Relative molecular mass Fe2 O3 = (56 × 2) + (16 × 3) = 112 + 48 = 160 2Al + Fe2 O3 Fe2 O3 1 mole 160 g 160 g Fe2 O3 → → → → → 1 g Fe2 O3 112 → –––– g Fe 160 30 g Fe2 O3 30 × 112 → g Fe 160 Al2 O3 + 2Fe 2Fe (shortened version of equation) 2 moles 2 (56) g 112 g Fe = 21 g Fe W11.11 Relative mol. mass NH4 NO3 = 14 + (1 × 4) + 14 + (16 ×3) = 14 + 4 +14 + 48 = 80 NH4 NO3 NH4 NO3 1 mole i.e. 80 g NH4 NO3 80 g NH4 NO3 80 –––––– g NH4 NO3 22,400 → → → → → N2 O + 2H2 O N2 O (shortened version of equation) 1 mole 22.4 L of N2 O at s.t.p. 22,400 cm3 of N2 O → 1cm3 of N2 O 550 × 80 g NH4 NO3 → 550 cm3 of N2 O 22,400 = 1.96 g NH4 NO3 104 Chemistry Live! – Worked Solutions W11.12 Rel. molecular mass CaC2 = 40 + (12 × 2) = 40 + 24 = 64 CaC2 + 2H2 O CaC2 1 mole i.e. 64 g CaC2 64 g CaC2 64 g CaC2 22,400 → → → → → C2 H2 + Ca(OH)2 C2 H2 (shortened version of equation) 1 mole 22.4 L of C2 H2 at s.t.p. 22,400 cm3 of C2 H2 → 1cm3 of C2 H2 350 × 64 g CaC2 → 350cm3 of C2 H2 22,400 = 1 g CaC2 W11.13 Relative mol. mass NH4 Cl = 14 + (1 × 4) + 35.5 = 14 + 4 + 35.5 = 53.5 2NH4 Cl + Ca(OH)2 2NH4 Cl 2 moles 2 (53.5) g i.e. 107 g NH4 Cl 107 g NH4 Cl 107 g NH4 Cl 44,800 → 2NH3 + CaCl2 + 2H2 O → 2NH3 (shortened version of equation) → 2 moles → 2 (22.4) L of NH3 at s.t.p. → 44.8 L of NH3 → 44,800 cm3 of NH3 →1cm3 of NH3 107 × 800 g NH4 Cl → 800 cm3 of NH3 44,800 = 1.91 g NH4 Cl 105 Chemistry Live! – Worked Solutions W11.14 Relative mol. mass KClO 3 = 39 + 35.5 + (16 × 3) = 39 + 35.5 + 48 = 122.5 2KClO 3 2KClO 3 2 moles 2 (122.5) g i.e. 245 g KClO3 245 g KClO 3 → → → → → → 2KCl + 3O2 3O2 (shortened version of equation) 3 moles 3 (22.4) L of O2 at s.t.p 67.2 L of O2 67,200 cm3 of O2 245 g KClO 3 → 1cm3 of O2 67,200 700 × 245 g KClO 3 → 700 cm3 of O2 67,200 = 2.55 g KCl W11.15 Mass number of moles of Cu = Rel. atomic mass 12.7 = = 0.2 63.5 mass number of moles of S = Rel. atomic mass 3.2 = = 0.1 32 (iii) Ratio of Cu : S = 0.2 : 0.1 = 2 : 1 (iv) Cu2 S copper (I) sulfate 106 Chemistry Live! – Worked Solutions W11.16 Relative mol. mass CaCO3 = 40 + 12 + (16 × 3) = 40 + 12 + 48 = 100 2CaCO3 + 2SO2 + O2 → 2CaSO4 + 2CO2 2 moles of CaCO3 reacts with 2 moles of SO2 1 mole of CaCO3 reacts with 1 mole of SO2 100 g CaCO3 reacts with 22.4 L of SO2 22.4 1 g CaCO3 reacts with L of SO2 100 1000 × 22.4 1000g CaCO3 reacts with L of SO2 100 = 224 L of SO2 W11.17 Na2 SO3 + 2HCl → 2NaCl + SO2 + H2 O (i) Relative mol. mass Na2 SO3 = (23 × 2) + 32 + (16 × 3) = 46 + 32 + 48 = 126 mass number of moles of Na2 SO3 = Rel. mol. Mass 6.3 = = 0.05 126 (ii) Na2 SO3 → SO2 (shortened version of equation) 1 mole → 1 mole 1 mole → 22.4 L 0.05 mole of Na2 SO3 → (0.05 × 22.4) L of SO2 at s.t.p. = 1.12 L of SO2 (iii) 1 mole of SO2 contains 6 ×1023 molecules 22.4 L of SO2 contains 6 × 1023 molecules 6 × 1023 1 L of SO2 contains molecules 22.4 1.12 × 6 × 1023 1.12 L of SO2 contains molecules 22.4 = 3 × 1022 molecules 107 Chemistry Live! – Worked Solutions W11.18 4FeS2 + 11O2 → 2Fe2 O3 + 8SO2 (i) Rel. mol. mass FeS2 = 56 + (32 × 2) = 56 + 64 = 120 Rel. mol. mass Fe2 O3 = (56 × 2) + (16 × 3) = 112 + 48 = 160 i.e. 4FeS2 4 moles 4(120) g 480 g FeS2 → → → → 1 g FeS2 320 → g Fe2 O3 480 9.6 g FeS2 → 2Fe2 O3 (shortened version of equation) 2 moles 2(160) g 320 g Fe2 O3 9.6 × 320 480 = 6.4 g Fe2 O3 (ii) 4FeS2 4 moles 4(120) g 480 g FeS2 → 8SO2 (shortened version of equation) → 8 moles → 8 (22.4) L → 179.2 L of SO2 at s.t.p. 1 g FeS2 179.2 → L of SO2 480 9.6 × 179.2 9.6 g FeS2 → of SO2 480 = 3.584 L of SO2 108 Chemistry Live! – Worked Solutions 1 mole of SO2 contains 6 ×1023 molecules 22.4 L of SO2 contains 6 × 1023 molecules (iii) 6 × 1023 1 L of SO2 contains molecules 22.4 3.584 × 6 × 1023 3.584 L of SO2 contains molecules 22.4 = 9.6 × 1022 molecules W11.19 (a) Element Percentage Carbon 38.7 Hydrogen 9.68 Oxygen 100 – (38.7 + 9.68) = 100 – 48.38 = 51.62 Percentage ––––––––––––– Rel. At. Mass 38.7 ––––– = 3.23 12 9.68 ––––– = 9.68 1 Simplest ratio (divide by 3.23) 3.23 –––– = 1 3.23 9.68 –––– = 3 3.23 51.62 ––––– = 3.23 16 3.23 –––– = 1 3.23 i.e. Empirical formula = CH3 O (b) Molecular Formula = empirical formula × n 62 = (CH3 O) × n 62 = [12 + (1 × 3) + 16] n 62 = (12 + 3 + 16) n 62 = 31n n=2 ⇒ Molecular Formula = (CH3 O) × 2 = C2 H6 O2 i.e. Molecular Formula = C2 H6 O2 109 Chemistry Live! – Worked Solutions W11.20 MnO2 + 4HCl → MnCl2 + Cl2 + 2H2 O (i) Rel. mol. mass MnO2 = 55 + (16 × 2) = 55 + 32 = 87 mass number of moles of MnO2 = ––––––––––––– Rel. mol. mass 4.35 = –––– = 0.05 87 (ii) 1 mole of MnO2 reacts with 4 moles of HCl ⇒ 0.05 mole of MnO 2 reacts with (0.05 × 4) mole of HCl = 0.2 mole of HCl (iii) Rel. mol. mass MnCl2 = 55 + (35.5 × 2) = 55 + 71 = 126 MnO2 → MnCl2 (shortened version of equation) 1 mole → 1 mole 0.05 mole → 0.05 mole Mass of MnCl2 = Number of moles × Rel. mol. mass = 0.05 × 126 = 6.3 g (iv) MnO2 → Cl2 (shortened version of equation) 1 mole → 1 mole 1 mole → 22.4 L 0.05 mole MnO 2 → (0.05 × 22.4) L of Cl2 at s.t.p. = 1.12 L of Cl2 (v) 1 mole of Cl2 contains 6 × 1023 molecules 0.05 mole of Cl2 contains 0.05 × 6 ×1023 molecules = 3 ×1022 molecules 110 Chemistry Live! – Worked Solutions Workbook - Chapter 13 – Volumetric Analysis: Acid - Base W 13.1 37.9 % w/v HCl means there are 37.9 g HCl in 100 g of solution ⇒ 100 1 g HCl in g of solution 37.9 5 × 100 5 g HCl in g of solution 37.9 = 13.19 g W13.2 (a) 0.54 g/L = 0.54 × 1000 mg/L = 540 mg/L = 540 ppm (b) 0.18 g/L = 0.18 × 1000 mg/L = 180 mg/L = 180 ppm (c) 0.077 g/100 cm3 = 0.077 × 10 g/L = 0.77 g/L = 0.77 × 1000 mg/L = 770 mg/L = 770 ppm (d) 0.0009 g/100 cm3 = 0.0009 × 10 g/L = 0.009 g/L = 0.009 × 1000 mg/L = 9 mg/L = 9 ppm 111 Chemistry Live! – Worked Solutions W13.3 (a) Rel. mol mass HCl = 1 + 35.5 = 36.5 36.5 g HCl in 1L of solution → 1M solution 1 1g HCl in 1L of solution → M solution 36.5 65 65 g HCl in 1L of solution → M solution 36.5 = 1.78 M (b) Rel. mol mass KOH = 39 + 16 + 1 = 56 56 g KOH in 1L of solution → 1M solution 1 1 g KOH in 1L of solution → M solution 56 25 25 g KOH in 1L of solution → M solution 56 25 × 4 25 g KOH in 250 cm of solution → M solution 56 3 = 1.79 M (c) Rel. mol mass H2 SO4 = 2(1) + 32 + 4(16) = 2 + 32 + 64 = 98 98 g H2 SO4 in 1L of solution → 1M solution 1 1g H2 SO4 in 1L of solution → M solution 98 22 22 g H2 SO4 in 1L of solution → M solution 98 22 × 10 22 g H2 SO4 in 100 cm of solution → M solution 98 3 = 2.24 M 112 Chemistry Live! – Worked Solutions (d) Rel. mol mass NaOH = 23 + 16 + 1 = 40 40 g NaOH in 1L of solution → 1M solution 1 1 g NaOH in 1L of solution → M solution 40 10 10 g NaOH in 1L of solution → M solution 40 10 10g NaOH in 2 L of solution → M solution 40 × 2 = 0.125 M (e) Rel. mol mass Na2 CO3 = 2(23) + 12 + 3(16) = 46 + 12 + 48 = 106 106 g Na2 CO3 in 1L of solution → 1M solution 1 1 g Na2 CO3 in 1L of solution → M solution 106 12.5 12.5 g Na2 CO3 in 1L of solution → M solution 106 12.5 × 5 12.5 g Na2 CO3 in 200 cm3 of solution → M solution 106 = 0.59 M 113 Chemistry Live! – Worked Solutions W13.4 80 mg /100 cm3 = 0.08 g /100 cm3 Rel. mol mass C2 H5 OH = 2(12) + 5(1) + 16 +1 = 24 + 5 + 16 + 1 = 46 46 g C2 H5 OH in 1L of solution → 1M solution 1 1 g C2 H5 OH in 1L of solution → M solution 46 0.08 0.08 g C2 H5 OH in 1L of solution → M solution 46 0.08 × 10 0.08 g C2 H5 OH in 100 cm3 of solution → M solution 46 . = 0.0174 M W13.5 (a) Volume × Molarity Number of moles of NaOH = 1000 20 × 0.1 = 1000 = 2 × 10-3 mole = 2 × 10-3 × 40 = 0.08 g (b) Volume × Molarity Number of moles of HNO3 = 1000 25 × 0.01 = ––––––––– 1000 = 2.5 × 10-4 moles = 2.5 × 10-4 × 63 (Mr HNO3 = 1 + 14 + 3(16) = 63 = 0.0158 g 114 Chemistry Live! – Worked Solutions (c) Number of moles of NH3 Volume × Molarity = 1000 750 × 0.12 = 1000 = 0.09 moles = 0.09 × 17 (Mr NH3 = 14 + 3(1) = 17) = 1.53 g (d) Number of moles of HCl Volume × Molarity = 1000 2000 × 2 = 1000 = 4 moles = 4 × 36.5 (Rel. mol mass HCl = 1 + 35.5 = 36.5) = 146 g (e) Number of moles of H2 SO4 Volume × Molarity = 1000 20 × 0.1 = 1000 = 2 × 10-3 moles = 2 × 10-3 × 98 = 0.196 (Mr H2 SO4 = 2(1) + 32 + 4(16) = 98) 115 Chemistry Live! – Worked Solutions W13.6 Mg + 2HCl → MgCl2 + H2 Number of moles of HCl Volume × Molarity = 1000 50 × 2 = 1000 = 0.1 moles From the balanced equation, 2 moles of hydrochloric acid react with one mole of magnesium 0.1 ⇒ = 0.05 moles of Mg react. 2 = 0.05 × 24 = 1.2 g W13.7 CaCO3 + 2HCl → CaCl2 + H2 O + CO2 Rel. mol mass CaCO3 = 40 + 12 + 3(16) = 40 + 12 + 48 = 100 Mass in g 10 Number of moles of CaCO3 = = = 0.1 Rel. mol. Mass 100 From the balanced equation, 2 moles of hydrochloric acid react with one mole of CaCO3 . ⇒ (0.1 × 2) moles = 0.2 moles of HCl react. Volume × Molarity Number of moles of HCl = 1000 Number of moles of HCl × 1000 ⇒ Volume = Molarity 0.2 × 1000 = 3 = 66.67 cm3 116 Chemistry Live! – Worked Solutions W13.8 Given: Vol dil = ? M dil = 0.01 M Vol conc = 20 cm3 M conc = 1 M Vol dil × M dil 1000 Vol dil × 0.01 Vol conc × M conc 1000 = = 20 × 1 20 × 1 ⇒ Vol dil = 0.01 = 2000 cm3 i.e. 20 cm3 of 1 M acid would have to be diluted to 2000 cm3 W13.9 Given: Voldil = 2000 cm3 Mdil = 2 M Volconc = ? Mconc = 16 M Vol dil × M dil 1000 2000 × 2 = Vol conc × M conc 1000 = Vol conc × 16 ⇒ Vol conc 2,000 × 2 = 16 = 250 cm3 i.e. 250 cm3 of 16 M ammonia would have to be diluted to 2 L. W13.10 Given: Voldil = 2,500 cm3 Mdil = 20 volume Volconc = ? Mconc = 100 volume Vol dil × M dil 1000 = Vol conc × M conc 1000 2,500 × 20 = Vol conc × 100 2,500 × 20 ⇒ Vol conc = 100 = 500 cm3 i.e. 500 cm3 of 100 volume H2 O2 would have to be diluted to 2.5 L. 117 Chemistry Live! – Worked Solutions W13.12 Balanced equation: Ca(OH)2 + 2HCl → CaCl2 + 2H2 O Given: Va = 15.2 cm3 Ma = 0.05 M na = 2 Vb =25 cm3 Mb = ? nb = 1 HCl Ca(OH)2 Va × Ma na = 15.2 × 0.05 –––––––––– 2 Vb × Mb nb 25 × Mb = ––––––– 1 15.2 × 0.05 ⇒ Mb = –––––––––– 2 × 25 = 0.0152 moles/L = 0.0152 × 74 (Mr Ca(OH)2 = 74) = 1.12 g / L Answers: (a) 0.0152 moles/L (b) 1.12 g/L W13.13 (a) Balanced equation: H2 C2 O4 + 2NaOH → Na2 C2 O4 + 2H2 O Given: Va = 18.7 cm3 Ma = ? na = 2 Vb =25 cm3 Mb = 0.12 M nb = 1 H2 C2 O4 NaOH Va × Ma –––––––– na Vb × Mb –––––––– nb = 18.7 × Ma ––––––––– 1 25 × 0.12 = ––––––––– 2 25 × 0.12 ⇒ Ma = –––––––––– 2 ×18.7 = 0.08 moles / L = 0.08 × 90 ( Mr H2 C2 O4 = 90) = 7.2 g / L Answers: (a) 0.08 moles/L (b) 7.2 g/L 118 Chemistry Live! – Worked Solutions W13.14 Balanced equation: CH3 COOH + NaOH → CH3 COONa + H2 O Given: Va = 20.25 cm3 Ma = ? na = 1 Vb =25 cm3 Mb = 0.15 M nb = 1 CH3 COOH Va × Ma –––––––– na NaOH 20.25 × Ma –––––––––– 1 = Vb × Mb –––––––– nb 25 × 0.15 = ––––––––– 1 25 × 0.15 ⇒ Ma = ––––––––– 20.25 = 0.1852 moles/L ⇒ Concentration of original solution = 0.1852 × 5 (5 times more concentrated) = 0.926 moles/L = 0.926 × 60 (Mr CH3 COOH = 60) = 55.56 g / L = 5.56 g /100 cm3 = 5.56 % w / v Answers = (a) 0.926 moles / L (b) 55.56 g / L (c) 5.56 % 119 Chemistry Live! – Worked Solutions W13.15 Balanced equation: CH3 COOH + NaOH → CH3 COONa + H2 O Given: Va = 12.35 cm3 Ma = ? na = 1 Vb =25 cm3 Mb = 0.12 M nb = 1 CH3 COOH NaOH Va × Ma –––––––– na = Vb × Mb ––––––– nb 12.35 × Ma ––––––––– 1 25 × 0.12 = –––––––– 1 25 × 0.12 ⇒ Ma = ––––––––– 12.35 = 0.2429 moles / L ⇒ Concentration of original solution = 0.2429 × 4 (4 times more concentrated) = 0.972 moles/L = 0.972 × 60 (Mr CH3 COOH = 60) = 58.32 g/L = 5.83 g/100 cm3 = 5.83 % w/v Answers = (a) 0.972 moles / L (b) 58.32 g / L (c) 5.83 % 120 Chemistry Live! – Worked Solutions W13.16 (a) Balanced equation: H2 C2 O4 + 2NaOH → Na2 C2 O4 + 2H2 O + CO2 Given: Va = 20 cm3 Ma = ? na = 1 Vb =22.22 cm3 Mb = 0.09 M nb = 2 H2 C2 O4 Va × Ma ––––––– na NaOH = 20 × Ma ––––––– = 1 Vb × Mb ––––––– nb 22.22 × 0.09 ––––––––––– 2 22.22 × 0.09 ⇒ Mb = ––––––––––– 2 × 20 = 0.05 moles/L 1 mole H2 C2 O4 = 2(1) + 2(12) + 4(16) = 2 + 24 + 64 = 90 g ⇒ 0.05 moles H2 C2 O 4 = 0.05 × 90 = 4.5 g ⇒ Mass of water of crystallisation = 6.3 – 4.5 = 1.8 g 1.8 % Water of crystallisation = –––– × 100 = 28.57 % 6.3 (b) Next, calculate the value of x in the formula H2 C2 O4 xH2 O. Note from the above that by dissolving 6.3 g of the crystals of H2 C2 O4 xH2 O in 1 L of solution, we obtain a solution which contains 0.05 moles. Therefore, 0.05 moles H2 C2 O4 .xH2 O = 6.3 g 6.3 1 mole H2 C2 O4 .xH2 O = –––– 0.05 = 126 i.e. Rel. mol mass of H2 C2 O4 .xH2 O = 126 ⇒ 2(1) + 2(12) + 4(16) + x(2 +16) = 126 90 + 18x = 126 18x = 36 x= 2 i.e. formula is H2 C2 O4 .2H2 O Answer: (a) % Water of crystallisation = 28.57 % (b) x = 2 121 Chemistry Live! – Worked Solutions W13.17 Balanced equation: H2 C2 O4 + 2NaOH → Na2 C2 O4 + 2H2 O + CO2 Given: Va = 25 cm3 Ma = ? na = 1 Vb =22.75 cm3 Mb = 0.35 M nb = 2 H2 C2 O4 NaOH Va × Ma ––––––– na Vb × Mb ––––––– nb = 25 × Ma 22.75 × 0.35 –––––––– = ––––––––––– 1 2 22.75 × 0.35 ⇒ Mb = ––––––––––– 2 × 25 = 0.1593 moles/L 0.1593 moles H2 C2 O4 .xH2 O per litre = (0.1593 / 4) moles H2 C2 O4 .xH2 O / 250cm3 = 0.0398 moles H2 C2 O4 .xH2 O/250 cm3 Note from the above that by dissolving 5 g of the crystals of H2 C2 O4 xH2 O in 250 cm3 of solution, we obtain a solution which contains 0.0398 moles. Therefore, 0.0398 moles H2 C2 O4 .xH2 O = 5 g 5 1 mole H2 C2 O4 .xH2 O = –––––– 0.0398 = 125.63 i.e. Rel. mol mass of H2 C2 O4 .xH2 O = 125.63 ⇒ 2(1) + 2(12) + 4(16) + x(2 +16) = 125.63 90 + 18x = 125.63 18x = 35.63 x = 1.98 ≈ 2 i.e. formula is H2 C2 O4 .2H2 O Answer: x = 2 Yes – he results obtained by both students are consistent. 122 Chemistry Live! – Worked Solutions Workbook Chapter 15 – Volumetric Analysis: Oxidation W15.1 Balanced equation: MnO4 - + 8H+ + 5Fe2+ → Mn2+ + 5Fe3+ + 4H2 O Given:Vo =28.5 cm3 Mo = ? no = 1 Vr =25 cm3 Mred = 0.11 M nr = 5 MnO4 - Fe2+ Vo × Mo Vr × Mred ––––––– = –––––––– no nr 28.5 × Mo ––––––––– 1 = 25 × 0.11 –––––––– 5 25 × 0.11 ⇒ Mo = ––––––––– 5 × 28.5 = 0.0193 moles/L = 0.0193 × 158 (Mr KMnO 4 = 158) = 3.05 g/L Answer: (a) 0.0193 moles/L (b) 3.05 g/L W15.2 Balanced equation: MnO4 - + 8H+ + 5Fe2+ → Mn2+ + 5Fe3+ + 4H2 O Given: Vo =22.5 cm3 Mo = 0.02 M no = 1 Vred =25 cm3 Mr = ? nr = 5 MnO4 - Fe2+ Vo × Mo Vr × Mred ––––––– = ––––––––– no nr 22.5 × 0.02 –––––––––– 1 ⇒ Mred = 25 × Mred ––––––––– 5 22.5 × 0.02 × 5 = ––––––––––––– 25 = 0.09 moles/L = 0.09 × 392 (Mr (NH4 )2 (SO4 )FeSO4 .6H2 O = 392) = 35.28 g / L Answer: (a) 0.09 moles/L (b) 35.28 g/L 123 Chemistry Live! – Worked Solutions W15.3 (a) Balanced equation: MnO4 - + 8H+ + 5Fe2+ → Mn2+ + 5Fe3+ + 4H2 O MnO4 - Given: Vo =23.5 cm3 Mo = 0.025 M no = 1 Vr =25 cm3 Mred = ? nr = 5 Vo × Mo –––––––– no Fe2+ = Vr × Mre ––––––– nr 23.5 × 0.025 25 × Mred ––––––––––– = ––––––––– 1 5 ⇒ Mred 23.5 × 0.025 × 5 = –––––––––––––– 25 = 0.1175 moles/L (b) 0.1175 moles FeSO4 / L = = = = (0.1175 / 4) moles FeSO4 / 250 cm3 0.0294 moles FeSO4 / 250 cm3 0.0294 × 56 (Relative atomic mass Fe = 56) 1.65 g / 250 cm3 1.65 % Fe in steel sample = ––––– × 100 = 89.19 % 1.85 Answers: (a) 0.1175 moles/L, (b) 1.65 g, 89.19% 124 Chemistry Live! – Worked Solutions W15.4 (b) Balanced equation: MnO4 - + 8H+ + 5Fe2+ → Mn2+ + 5Fe3+ + 4H2 O MnO4 - Given: Vo = 19.65 cm3 Mo = 0.024 M no = 1 Vred = 25 cm3 Mr = ? nr = 5 Vo × Mo –––––––– no Fe2+ 19.65 × 0.024 –––––––––––– 1 = ⇒ Mred Vr × Mred ––––––––– nr 25 × Mred = –––––––– 5 19.65 × 0.024 × 5 = ––––––––––––––– 25 = 0.0943 moles/L 0.0943 moles FeSO4 .xH2 O / L = (0.0943 / 4) moles FeSO4 .xH2 O / 250 cm3 = 0.0236 moles FeSO4 .xH2 O / 250 cm3 i.e. by dissolving 5.71 g of the crystals of FeSO4 .xH2 O in 250 cm3 of solution, we obtain a solution which contains 0.0236 moles. Therefore, 0.0236 moles FeSO4 .xH2 O = 5.71 g 1 mole FeSO4 .xH2 O ⇒ 56 5.71 = –––––– 0.0236 = 241.95 + 32 + 4(16) + x(2 + 16) = 241.95 152 + 18x = 241.95 18x = 89.95 x=5 i.e. formula is FeSO4 .5H2 O Answer: (b) x = 5 125 Chemistry Live! – Worked Solutions W15.5 (ii) 392 g of (NH4 )2 (SO4 )FeSO4 .6H2 O in 1 L of solution → 1 M solution 1 1 g of (NH4 )2 (SO4 )FeSO4 .6H2 O in 1 L of solution → ––– M solution 392 1 × 11.76 11.76 g of (NH4 )2 (SO4 )FeSO4 .6H2 O in 1 L of solution → –––––––––– M solution 392 4 × 11.76 10.52 g of (NH4 )2 (SO4 )FeSO4 .6H2 O in 250 cm3 of solution → –––––––––– M solution 392 = 0.12 M (v) Balanced equation: MnO4 - + 8H+ + 5Fe2+ → Mn2+ + 5Fe3+ + 4H2 O Given:Vo =33.3 cm3 Mo = ? no = 1 Vred =25 cm3 Mr = 0.12 M nr = 5 MnO4 Vo × Mo –––––––– no Fe2+ = Vr × Mred –––––––– nr 33.3 × Mo –––––––– = 1 25 × 0.12 ––––––––– 5 ⇒ Mo 25 × 0.12 = ––––––––– 5 × 33.3 = 0.018 moles/L Answer: (ii) 0.12 M, (v) 0.018 M 126 Chemistry Live! – Worked Solutions W15.6 (vi) (a) Balanced equation: MnO4 - + 8H+ + 5Fe2+ → Mn2+ + 5Fe3+ + 4H2 O Given:Vo = 22.5 cm3 Mo = 0.02 M no = 1 Vr =25 cm3 Mred = ? nr = 5 MnO4 - Fe2+ Vo × Mo ––––––– no = Vr × Mred ––––––––– nr 22.5 × 0.02 ––––––––––– 1 = 25 × Mred –––––––– 5 ⇒ Mr 22.5 × 0.02 × 5 = ––––––––––––– 25 = 0.09 moles / L = 0.09 × 284 = 25.56 g / L Rel. mol mass (NH4 )2 (SO4 )FeSO4 = 2(14) + 8(1) + 32 + 4(16) + 56 + 32 + 4(16) = 284 25.56 g (NH4 )2 (SO4 )FeSO4 / L = (25.56 / 4) g (NH4 )2 (SO4 )FeSO4 / 250 cm3 = 6.39 g (NH4 )2 (SO4 )FeSO4 / 250 cm3 We are told that we dissolved 8.82 g (NH4 )2 (SO4 )FeSO4 . xH2 O / 250 cm3 ⇒ mass of H2 O / 250 cm3 = 8.82 – 6.39 = 2.43 g % water of crystallisation mass of water = ––––––––––––––––––––––––––––– × 100 mass of (NH4 )2 (SO4 )FeSO4 . xH2 O 2.43 = ––––– × 100 = 27.55 % 8.82 0.09 moles (NH4 )2 (SO4 )FeSO4 .xH2 O/L = (0.09/4) moles (NH4 )2 (SO4 )FeSO4 .xH2 O / 250 cm3 = 0.0225 moles (NH4 )2 (SO4 )FeSO4 .xH2 O/250 cm3 i.e. by dissolving 8.82 g of the crystals of (NH4 )2 SO4 FeSO4 .xH2 O in 250 cm3 of solution, we obtain a solution which contains 0.0225 moles. Therefore, 0.0225 moles (NH4 )2 SO4 FeSO4 .xH2 O = 8.82 g 127 Chemistry Live! – Worked Solutions 8.82 1 mole (NH4 )2 SO4 FeSO4 .xH2 O = –––––– 0.0225 = 392 ⇒ 2(14) + 8(1) + 32 + 4(16) + 56 + 32 + 4(16) +x(2 +16) = 392 284 + 18x = 392 18x = 108 x = 6 i.e. formula is (NH4 )2 SO4 FeSO4 .6H2 O Answer: (vi) (a) 0.09 M (b) 25.56 g/L, 27.55%, x = 6. W15.7 (iii) (a) Balanced equation: MnO4 - + 8H+ + 5Fe2+ → Mn2+ + 5Fe3+ + 4H2 O Given:Vo = 5.47 cm3 Mo = 0.015 M no = 1 Vr = 20 cm3 Mred = ? nr = 5 MnO4 Vo × Mo ––––––– = no Fe2+ Vr × Mred –––––––– nr 5.47 × 0.015 20 × Mred ––––––––––– = –––––––– 1 5 5.47 × 0.015 × 5 ⇒ Mr = –––––––––––––– 20 = 0.021 moles/L = 0.021 × 152 = 3.19 g / L (Rel. mol mass FeSO4 = 56 + 32 + 4(16) = 152) Therefore, in the 250 cm3 volumetric flask there are 3.19 / 4 g = 0.798 g FeSO4 i.e. 6 tablets contain 0.798 g FeSO4 ⇒ 1 tablet contains (0.798 / 6) g = 0.133 g FeSO4 128 Chemistry Live! – Worked Solutions (b) Rel. atomic mass Fe % of Fe in FeSO4 = –––––––––––––––––– × 100 Rel. mol. mass FeSO4 56 = –––– × 100 = 36.84 % 152 ⇒ Mass of Fe in each tablet = 36. 84 % of 0.133 g 36.84 = ––––– × 0.133 = 0.049 g 100 (c) 1.47 Mass of 1 tablet = –––– = 0.245 g 6 Mass of FeSO4 in tablet % FeSO4 in each tablet = –––––––––––––––––––– × 100 Mass of 1 tablet 0.133 = ––––– × 100 = 54.29 % 0.245 Answer: (a) 0.133 g (b) 0.049 g (c) 54.29% W15.8 (iii) (a) Balanced equation: MnO4 - + 8H+ + 5Fe2+ → Mn2+ + 5Fe3+ + 4H2 O Given:Vo = 5.75 cm3 Mo = 0.015 M no = 1 Vr =25 cm3 Mred = ? nr = 5 MnO4 Vo × Mo ––––––––– no Fe2+ = Vr × Mred ––––––––– nr 5.75 × 0.015 25 × Mr ––––––––––– = –––––––– 1 5 5.75 × 0.015 × 5 ⇒ Mr = –––––––––––––– 25 129 Chemistry Live! – Worked Solutions = 0.017 moles / L = 0.017 × 152 = 2.58 g / L (Rel. mol mass FeSO4 = 56 + 32 + 4(16) = 152) Therefore, in the 250 cm3 volumetric flask there are 2.58 / 4 = 0.645 g FeSO4 i.e. 5 tablets contain 0.645 g FeSO4 ⇒ 1 tablet contains (0.645 / 5) g = 0.129 g FeSO4 (b) Rel. atomic mass Fe % of Fe in FeSO4 = –––––––––––––––––– × 100 Rel. mol. mass FeSO4 56 = ––– × 100 = 36.84 % 152 ⇒ Mass of Fe in each tablet = 36. 84 % of 0.129 g 36.84 = ––––– × 0.129 = 0.048 g 100 (c) 1.20 Mass of 1 tablet = ––––– = 0.24 g 5 Mass of FeSO4 in tablet % FeSO4 in each tablet = ––––––––––––––––––––– × 100 Mass of 1 tablet 0.129 = ––––– × 100 = 53.75 % 0.24 Answer: (iii) (a) 0.129 g 130 (b) 0.048 g (c) 53.75% Chemistry Live! – Worked Solutions W15.9 (a) Balanced equation: I2 + 2S2 O3 2- → S4 O6 2- + 2IGiven:Vo = 25 cm3 Mo = ? no = 1 Vr =22.15 cm3 Mred = 0.12 M nr = 2 I2 S2 O3 2- Vo × Mo –––––––– no = Vr × Mred –––––––– nr 25 × Mo –––––––– 1 22.15 × 0.12 = –––––––––––– 2 ⇒ Mo 22.15 × 0.12 = –––––––––– 2 × 25 = 0.0532 moles/L = 0.0532 × 254 = 13.51 g/L Answer: (a) 0.0532 moles/L, (b) 13.51 g/L 131 Chemistry Live! – Worked Solutions W15.10 (a) 2MnO 4 - + 10I- + 16H+ → 2Mn2+ + 5I2 + 8H2 O I2 + 2S2 O3 2- → S4 O6 2- + 2IFrom the balanced equations, we see that 2 moles of MnO 4 - produce five moles of I2 and these 5 moles of I2 would then react with 10 moles of S2 O3 2-. i.e. 2MnO4 - = 5I2 = 10S2 O3 2Given: Vo = 25 cm3 Mo = 0.022 M no = 2 Vr = 22.45 cm3 Mr = ? nr = 10 MnO4 Vo × Mo ––––––– no 25 × 0.022 –––––––––– 2 ⇒ Mr S2 O3 2- = Vr × Mr ––––––– nr 22.45 × Mr = –––––––––– 10 25 × 0.022 × 10 = –––––––––––––– 2 × 22.45 = 0.1225 moles/L = 0.1225 × 248 = 30.38 g/L (Rel. molecular mass Na2 S2 O3 .5H2 O = 248) Answer: (a) 0.1225 moles/L, (b) 30.38 g/L 132 Chemistry Live! – Worked Solutions W15.11 (vi) (a) Balanced equation: 2S2 O3 2- + I2 → S4 O6 2- + 2IGiven: Vo = 25 cm3 Mo = 0.05 M no = 1 Vr = 31.2 + 31.3 = 31.25 cm3 2 Mred = ? nr = 2 S2 O3 2- I2 Vo × Mo ––––––– no V × Mred = –––––––– nr 25 × 0.05 31.25 × Mred –––––––––– = –––––––––– 1 2 ⇒ Mred = 25 × 0.05 × 2 –––––––––––– 31.25 = 0.08 moles/L = 0.08 × 248 = 19.84 g / L (Rel. mol mass Na2 S2 O3 .5H2 O = 248) Concentration of Na2 S2 O3 .5H2 O in g / L = number of moles /L × rel. mol mass (vii) 19.84 g Na2 S2 O3 .5H2 O / L = (19.84 / 2) g Na2 S2 O3 .5H2 O / 500 cm3 = 9.92 g Na2 S2 O3 .5H2 O / 500 cm3 9.92 % purity of sample = –––– × 100 = 99.2 % 10 Answer: (vi) (a) 0.08 moles/L, (b) 19.84 g/L (vii) 99.2% 133 Chemistry Live! – Worked Solutions W15.12 (a) ClO - + 2I- + 2H+ → Cl- + I2 + H2 O 2S2 O3 2- + I2 → S4 O6 2- + 2IFrom the balanced equations, we see that 1 mole of ClO - produce 1 moles of I2 and this 1 mole of I2 would then react with 2 moles of S2 O3 2-. i.e. 1ClO- = 1I2 = 2S2 O3 2Given:Vo = 25 cm3 Mo = ? no = 1 Vr =19.56 cm3 Mred = 0.25 M nr = 2 ClO - S2 O3 2- Vo × Mo ––––––– = no Vr × Mred –––––––– nr 25 × Mo 19.56 × 0.25 –––––––– = ––––––––––– 1 2 ⇒ Mo ⇒ Concentration of original solution 19.56 × 0.25 = ––––––––––– 2 × 25 = 0.0978 moles / L = 0.0978 × 5 (5 times more concentrated) = 0.489 M = 0.489 × 74.5 (Mr NaClO = 74.5) = 36.43 g/L = 3.643 g/100 cm3 = 3.64 % w / v Answer: (a) 0.489 moles/L, (b) 36.43 g/L, (c) 3.64% 134 Chemistry Live! – Worked Solutions Workbook Chapter 16 – Rates of Reaction W16.3 (ii) graph (iv) From graph: 1 24 cm of 0.2 M Na2 S2 O3 → –– = 0.01 s-1 t ⇒ t = 100 seconds W16.4 (iii) graph 3 (iv) (a) time required to liberate 8.75 × 10-3 moles of oxygen Rel. mol. mass O2 = 16 × 2 = 32 Mass of O2 = no. of moles × rel. mol. mass = 8.75 × 10-3 × 32 = 0.28 g From graph: 0.28 g → 1.3 minutes (b) number of moles of oxygen liberated after 2.5 minutes From graph: 2.5 minutes → 0.39 g number of moles of O2 mass = –––––––––––– Rel. mol. Mass 0.39 = –––– = 1.219 × 10-2 32 (c) 0.435 – 0.2925 0.1425 Instantaneous rate of reaction at 2 minutes = ––––––––––––– = –––––– 3 –1 2 = 0.07125 cm3 / minute 135 Chemistry Live! – Worked Solutions (v) Total loss in mass = 176.58 – 176.10 = 0.48 g mass number of moles of O2 = ––––––––––––– Rel. mol. Mass 0.48 = –––– = 0.015 32 2H2 O2 → 2H2 O + O2 2H2 O2 → O2 (shortened version of equation) 2 moles → 1 mole ⇒ 2 × 0.015 → 0.015 moles = 0.03 moles H2 O2 W16.5 (ii) graph (iii) From graph: 1 35 °C → Rate = –– = 0.036 s-1 t ⇒ t = 27.78 s W16.7 (iii) graph (iv) 1.75 minutes → 51 cm3 O2 At s.t.p, 1 mole of O2 occupies 22.4 L (22,400 cm3 ). 51 No. of moles of O2 = –––––– = 2.28 × 10-3 22,400 (v) At s.t.p, 1 mole of O2 occupies 22.4 L (22,400 cm3 ). ⇒ 2 × 10-3 mole of O2 occupies (2 × 10-3 × 22,400) cm3 = 44.8 cm3 3 From graph: 44.8 cm are liberated at a time of 1.2 minutes (vi) (a) Instantaneous rate of reaction at 0.5 minutes 50 – 6.5 = ––––––– = 43.5 cm3 / minute 1–0 = 43.5 cm3 / 60 seconds = 0.725 cm3 / second (b) 55 – 55 Instantaneous rate of reaction at 3 minutes = –––––––– = 0 cm3 / minute 3.5 –2.5 = 0 cm3 / 60 seconds = 0 cm3 / second 136 Chemistry Live! – Worked Solutions Workbook Chapter 17 – Chemical Equilibrium W17.7 CH3 COOH + C2 H5OH Initially: At Equil. : Conc. at equil. º CH3 COOC2 H5 + H2 O 1 4 0 0 1–x 4–x x x [x / V] [x / V] [1 – x / V] [4 – x / V] V is the volume of the container which we are not given in the question. [CH3 COOC2 H5 ] [H2 O] Kc = –––––––––––––––––––– [CH3 COOH] [C 2 H5 OH] (x / V) (x / V) = –––––––––––––––––– = 4 (1 – x / V) (4 – x / V) The V terms cancel out in the Kc expression (x) (x) ∴ ––––––––––– = 4 (1 – x) (4 – x) x2 –––––––––– = 4 4 – 5x + x2 ⇒ ⇒ ⇒ ⇒ ⇒ cross multiply x2 = 4 (4 – 5x + x2 ) x2 = 16 - 20x + 4x2 3x2 – 20x + 16 =0 solve quadratic equation using the formula: _______ –b ± √b2 - 4ac x = ––––––––––––– where a = 3, b = –20 and c = 16 2a ______________ 20 ± √(-20)2 – 4(3)(16) x = –––––––––––––––––––– 2(3) ___ 20 ± √208 20 ± 14.42 x = ––––––––––––– = –––––––––– 6 6 x = 34.42 = 5.74 or x = 5.58 6 6 = 0.93 137 Chemistry Live! – Worked Solutions Chemically, 5.74 does not make sense since we started with only 1 mole of CH3 COOH and 4 moles of C2 H5 OH. Therefore, we take the value of x = 0.93. Therefore equilibrium concentrations are :CH3 COOH = 1 – x = 1 – 0.93 = 0.07 mol/L C2 H5 OH = 4 – x = 4 - 0.93 = 3.07 mol/L CH3 COOC2 H5 = x = 0.93 mol/L H2 O = x = 0.93 mol/L Answer: Equilibrium concentration of CH3 COOC2 H5 = 0.93 mol/L Equilibrium concentration of H2 O = 0.93 mol/L W17.8 2HI Initially: At Equil. : • H2 + I2 0.1 0 0 1 – 0.02 0.01 0.01 [0.01] [0.01] Conc. at equil.: [0.08] Therefore equilibrium concentrations are: (a) I2 = 0.01 mol/L (b) HI = 0.08 mol/L Answer: (a) Equilibrium concentration of I2 = 0.01 mol/L (b) Equilibrium concentration of HI = 0.08 mol/L 138 = 0.08 Chemistry Live! – Worked Solutions W17.9 Rel molecular mass CH3 COOH = 12 + 3(1) + 12 + 2(16) + 1 = 12 + 3 + 12 + 32 + 1 = 60 Mass 36 Initial number of moles of CH3 COOH = ––––––––––––––––– = ––– = 0.6 Rel molecular mass 60 Mass 12 At equil. number of moles of CH3 COOH = –––––––––––––––– = ––– = 0.2 Rel molecular mass 60 Rel molecular mass C2 H5 OH = 2(12) + 5(1) + 16 + 1 = 24 + 5 + 16 +1 = 46 Mass 27.6 Initial number of moles of C2 H5 OH = ––––––––––––––––– = ––––– = 0.6 Rel molecular mass 46 CH3 COOH + Initially: At Equil. : C2 H5OH • CH3COOC2H5 + H2O 0.6 0.6 0 0.6 – 0.4 0.6 – 0.4 0.4 [0.2 / V] [0.2 / V] [0.4 / V] 0 0.4 = 0.2 = 0.2 Conc. at equil. [0.4 / V] V is the volume of the container which we are not given in the question. [CH3 COOC2 H5 ] [H2 O] (0.4 / V) (0.4 / V) Kc = ––––––––––––––––––– = ––––––––––––––– [CH3 COOH] [C 2 H5 OH] (0.2 / V) (0.2 / V) The V terms cancel out in the Kc expression (0.4) (0.4) ⇒ K c = –––––––– = 4 (0.2) (0.2) Mass 60 Initial number of moles of CH3 COOH = –––––––––––––––– = ––– = 1.0 Rel molecular mass 60 Rel molecular mass CH3 COOC2 H5 = 12 + 3(1) + 12 + 2(16) + 2(12) + 5(1) 139 Chemistry Live! – Worked Solutions = 12 + 3 + 12 + 32 + 24 + 5 = 88 Mass 70.4 At equil. number of moles of CH3 COOC2 H5 = ––––––––––––––––– = –––– = 0.8 Rel molecular mass 88 CH3 COOH + C2 H5 OH • CH3COOC2H5 + H2O Initially: 1 At Equil. : C 1 – 0.8 = 0.2 Conc. at equil. [0.2 / V] 0 0 0.8 0.8 [0.8 / V] [0.8 / V] C – 0.8 [C – 0.8 / V] Where C is the initial number of moles of ethanol and V is the volume of the container which we are not given in the question. [CH3 COOC2 H5 ] [H2 O] (0.8 / V) (0.8 / V) Kc = ––––––––––––––––––– = ––––––––––––––––– [CH3 COOH] [C 2 H5 OH] (0.2 / V) (C – 0.8 / V) The V terms cancel out in the Kc expression (0.8) (0.8) ⇒ K c = ––––––––––– = 4 (0.2) (C – 0.8) 0.64 ⇒ –––––––––– = 4 0.2C – 0.16 ⇒ ⇒ ⇒ ⇒ cross multiply and solve for C 0.64 = 4 (0.2C – 0.16) 0.64 = 0.8C – 0.64 0.8C = 1.28 C = 1.6 moles Answer Kc = 4 Number of moles of ethanol = 1.6 140 Chemistry Live! – Worked Solutions W17.10 SO2 (g) + NO2 (g) • SO3(g) + NO(g) [SO3 ] [NO] Kc = ––––––––––– [SO2 ] [NO2 ] Rel molecular mass SO2 = 32 + 2(16) = 32 + 32 = 64 Mass 7.68 Initial number of moles of SO2 = ––––––––––––––––– = –––– = 0.12 Rel molecular mass 64 Rel molecular mass NO2 = 14 + 2(16) = 14 + 32 = 46 Mass 4.6 Initial number of moles of NO2 = –––––––––––––––– = ––– = 0.1 Rel molecular mass 46 Rel molecular mass SO3 = 32 + 3(16) = 32 + 48 = 80 Mass 4.8 At equil. number of moles of SO3 = –––––––––––––––– = ––– = 0.06 Rel molecular mass 80 SO2 (g) Initially: 0.12 At Equil. : 0.12 – 0.06 = 0.06 Conc. at equil. [0.06 / V] + NO2 (g) 0.1 0.1 – 0.06 = 0.04 [0.04 / V] • SO3(g) + 0 0 0.06 [0.06 / V] NO(g) 0.06 [0.06 / V] V is the volume of the container which we are not given in the question. [SO3 ] [NO] (0.06 / V) (0.06 / V) Kc = ––––––––––– = ––––––––––––––––– [SO2 ] [NO2 ] (0.06 / V) (0.04 / V) The V terms cancel out in the Kc expression (0.06) (0.06) ⇒ K c = ––––––––––– = 1.5 (0.06) (0.04) Answer Kc = 1.5 141 Chemistry Live! – Worked Solutions W17.11 2HI • H2 + I2 Initially: 0 2 1 At equil.: 2x 2- x 1- x Conc. at equil. : (V =1 L) [2x] [H2 ][ I2 ] Kc = –––––––– [HI] 2 [2 – x] [1 –x] (2 – x) (1 – x) = ––––––––––– = 0.02 (2x) 2 2 – 3 x + x2 ⇒ –––––––––– = 0.02 4x2 cross multiply 2 – 3x + x2 = 0.02 (4x2 ) 2 – 3x + x2 = 0.08x2 0.92x2 – 3x + 2 = 0 solve quadratic equation using the formula _______ – b ± √b2 – 4ac x = –––––––––––––– where a = 0.92, b = – 3 and c = 2 2a _______________ 3 ± √(– 3)2 – 4(0.92)(2) ⇒ x = ––––––––––––––––––––– 2(0.92) _____ 3 ± √1.64 3 ± 1.28 x = –––––––––– = –––––––– 1.84 1.84 ⇒ ⇒ ⇒ ⇒ x = 4.28 = 2.33 1.84 or x = 1.72 = 0.93 1.84 Chemically, 2.33 does not make sense since we started with only 2 moles of H2 . Therefore, we take the value of x = 0.93. Therefore equilibrium concentrations are: HI = 2x = 2(0.93) = 1.86 mol/L H2 = 2 – x = 2 – 0.93 = 1.07 mol/L I2 = 1 – x = 1 – 0.93 = 0.07 mol/L Answer: Equilibrium concentration of HI = 1.86 mol/L Equilibrium concentration of H2 = 1.07 mol/L Equilibrium concentration of I2 = 0.07 mol/Ls 142 Chemistry Live! – Worked Solutions W17.12 • Initially: N2 O4(g) 0.1 2NO2(g) 0 At Equil. : 0.1 - x 2x Conc. at equil. : (V = 1 L) [0.1 - x] [2x] [NO2 ] 2 (2x) 2 Kc = ––––––– = –––––––– = 0.36 [N 2 O4 ] (0.1 - x) 4x2 ⇒ –––––– = 0.36 0.1 - x cross multiply 2 ⇒ 4x = 0.36 (0.1 - x) 2 ⇒ 4x = 0.036 – 0.36x 2 ⇒ 4x + 0.36x – 0.036 = 0 solve quadratic equation using the formula _______ -b ± √b2 - 4ac x = –––––––––––– where a = 4, b = 0.36 and c = -0.036 2a __________________ -0.36 ± √(0.36)2 – 4(4)( -0.036) ⇒ x = –––––––––––––––––––––––––– 2(4) ____ -0.36 ± √0.71 -0.36 ± 0.84 x = ––––––––––––– = –––––––––––– 8 8 ⇒ x = 0.48 = 0.06 8 or x = -1.2 8 = -0.15 Chemically, -0.15 does not make sense, therefore, we take the value of x = 0.06. Therefore equilibrium concentrations are:N2 O4 = 0.1 – x = 0.1 – 0.06 = 0.04 mol/L NO2 = 2x = 2 (0.06) = 0.12 mol/L Answer Equilibrium concentration of N2 O4 = 0.04 mol/L Equilibrium concentration of NO2 = 0.12 mol/L 143 Chemistry Live! – Worked Solutions Workbook Chapter 18 – pH and Indicators W 18.2 (a) pH = - log 10 [H+] = - log 10 (10-5 ) =5 + (b) pH = - log 10 [H ] = - log 10 (8.33 × 10-3 ) = 2.08 + (c) pH = - log 10 [H ] = - log 10 (2.25 × 10-1 ) = 0.65 + (d) pH = - log 10 [H ] = - log 10 (4.4 × 10-12 ) = 11.36 + (e) pH = - log 10 [H ] = - log 10 (3.9 × 10-9 ) = 8.41 W18.3 (a) pH = - log 10 [H+] = 1.16 log 10 [H+] = - 1.16 + ⇒ [H ] = antilog (- 1.16) = 0.07 mol/L (b) pH = - log 10 [H+] = 6.51 log 10 [H+] = - 6.51 + ⇒ [H ] = antilog (- 6.51) = 3.09 × 10-7 mol/L (c) pH = - log 10 [H+] = 14 log 10 [H+] = - 14 + ⇒ [H ] = antilog (- 14) = 1 × 10-14 mol/L (d) pH = - log 10 [H+] = 0.21 log 10 [H+] = - 0.21 + ⇒ [H ] = antilog (- 0.21) = 0.62 mol/L (e) pH = - log 10 [H+] = 10.48 log 10 [H+] = - 10.48 + ⇒ [H ] = antilog (- 10.48) = 3.31 × 10-11 mol/L 144 Chemistry Live! – Worked Solutions W18.4 (a) H2 SO4 → 2H+ + SO4 21 mole → 2 moles ⇒ 0.1 mole → 0.1 × 2 mole = 0.2 mole pH = - log 10 [H+] = -log 10 (0.2) = 0.70 (b) HCl → H+ + Cl1 mole → 1 mole ⇒ 0.2 mole → 0.2 mole pH = - log 10 [H+] = -log 10 (0.2) = 0.70 (c) HCl → H+ + Cl1 mole → 1 mole ⇒ 0.05 mole → 0.05 mole pH = - log 10 [H+] = -log 10 (0.05) = 1.30 (d) 0.007 g KOH / 500 cm3 = (0.007 × 2) g KOH / L = 0.014 g KOH / L Rel molecular mass KOH = 39 + 16 + 1 = 56 Mass in 1 L 0.014 Number of moles of KOH / L = –––––––––––––––– = –––––– = 0.00025 Rel molecular mass 56 KOH → K+ + OH1 mole → 1 mole ⇒ 0.00025 mole → 0.00025 mole pOH = - log 10 [OH-] = -log 10 (0.00025) = 3.60 pH = 14 – pOH =14 –3.60 = 10.40 (e) 0.049 g H2 SO4 / 200 cm3 = (0.049 × 5) g H2 SO4 / L = 0.245 g H2 SO4 / L Rel molecular mass H2 SO4 = 2(1) + 32 + 4(16) = 98 Mass in 1 L 0.245 Number of moles of H2 SO4 / L = –––––––––––––––– = ––––– = 0.0025 Rel molecular mass 98 H2 SO4 → 2H+ + SO4 21 mole → 2 mole ⇒ 0.0025 mole → 0.0025 × 2 mole = 0.005 mole + pH = - log 10 [H ] = -log 10 (0.005) = 2.30 145 Chemistry Live! – Worked Solutions W18.5 (a) NaOH → Na+ + OH1 mole → 1 mole ⇒ 0.33 mole → 0.33 mole pOH = - log 10 [OH-] = -log 10 (0.33) = 0.48 pH = 14 – pOH = 14 – 0.48 = 13.52 (b) KOH → K+ + OH1 mole → 1 mole ⇒ 0.001 mole → 0.001 mole pOH = - log 10 [OH-] = -log 10 (0.001) = 3 pH = 14 – pOH = 14 – 3 = 11 (c) 2 g NaOH / 250 cm3 = (2 × 4) g NaOH / L = 8 g NaOH / L Rel molecular mass NaOH = 23 + 16 + 1 = 40 Mass in 1L 8 Number of moles of NaOH / L = –––––––––––––––– = ––– = 0.2 Rel molecular mass 40 NaOH → Na+ + OH1 mole → 1 mole ⇒ 0.2 mole → 0.2 mole pOH = - log 10 [OH-] = -log 10 (0.2) = 0.70 pH = 14 – pOH = 14 – 0.70 = 13.30 (d) KOH → K+ + OH1 mole → 1 mole -5 -5 ⇒ 5 ×10 mole → 5 ×10 mole pOH = - log 10 [OH-] = -log 10 (5 ×10-5 ) = 4.30 pH = 14 – pOH =14 – 4.30 = 9.70 (e) 0.008 g KOH / 200 cm3 = (0.008 × 5) g KOH / L = 0.04 g KOH / L Rel molecular mass KOH = 39 + 16 + 1 = 56 Mass in 1 L 0.04 Number of moles of KOH / L = –––––––––––––––– = ––––– = 7.14 ×10-4 Rel molecular mass 56 KOH → K+ + OH1 mole → 1 mole -4 -4 ⇒ 7.14 ×10 mole → 7.14 ×10 mole pOH = - log 10 [OH ] = -log 10 (7.14 ×10-4 ) = 3.15 pH = 14 – pOH =14 –3.15 = 10.85 146 Chemistry Live! – Worked Solutions W18.6 Hydroxide ion concentration can be found by substituting into the formula: __________ [OH ] = √ Kb × Mbase _______________ = √ 1.8 ×10-5 × 0.05 _________ = √ 9 ×10-7 = 9.49 ×10-4 mol/L pOH = - log 10 [OH-] = -log 10 (9.49 ×10-4 ) = 3.02 pH = 14 – pOH =14 – 3.02 = 10.98 Answer: pH = 10.98 W18.7 Hydrogen ion concentration can be found by substituting into the formula:__________ + [H ] = √ Ka × Macid ____________ = √1.8 × 10-4 × 0.1 _________ = √ 1.8 × 10-5 = 4.24 × 10-3 mol/L pH = - log 10 [H+] = -log 10 (4.24 × 10-3 ) = 2.37 Answer: pH =2.37 W 18.8 Kw = [H+] [OH-] [H+] = [OH-] + 2 ⇒ K w = [H ] At 25 o C Kw = 10-14 = [H+]2 _____ ⇒ [H ] = √10-14 = 1×10-7 mol/L + pH = - log 10 [H+] = -log 10 (1×10-7 ) = 7 At 57 o C Kw = 9 ×10-14 = [H+]2 ________ ⇒ [H+] = √9 ×10-14 = 3 ×10-7 mol/L pH = - log 10 [H+] = -log 10 (3×10-7 ) = 6.52 Answer: pH at 25 o C = 7 pH at 57 o C = 6.52 147 Chemistry Live! – Worked Solutions W18.9 8 g CH3 COOH / 250 cm3 = (8 × 4) g CH3 COOH / L = 32 g CH3 COOH / L Rel molecular mass CH3 COOH = 12 + 3(1) + 12 + 2(16) + 1 = 60 Mass in 1 L 32 Number of moles of CH3 COOH / L = ––––––––––––––––– = ––– = 0.533 Rel molecular mass 60 CH3 COOH → CH3 COO- + H+ Hydrogen ion concentration can be found by substituting into the formula: _________ + [H ] = √ Ka × Macid _______________ = √1.8 × 10-5 × 0.533 ___________ = √ 9.594 × 10-6 = 3.1 × 10-3 mol/L pH = - log 10 [H+] = -log 10 (3.1 × 10-3 ) = 2.51 Answer: pH = 2.51 W18.10 3 g CH3 COOH / 250 cm3 = (3 × 4) g CH3 COOH / L = 12 g CH3 COOH / L Rel molecular mass CH3 COOH = 12 + 3(1) + 12 + 2(16) + 1 = 60 Mass in 1 L 12 Number of moles of CH3 COOH / L = ––––––––––––––––– = ––– = 0.2 Rel molecular mass 60 Hydrogen ion concentration can be found by substituting into the formula: _________ + [H ] = √ Ka × Macid _____________ = √ 1.8 × 10-5 × 0.2 _________ = √ 3.6 × 10-6 = 1.90 × 10-3 mol/L pH = - log 10 [H+] = -log 10 (1.9 × 10-3 ) = 2.72 Answer: pH = 2.72 148 Chemistry Live! – Worked Solutions W18.11 Acid concentration can be found by substituting into the formula: __________ + [H ] = √ Ka × Macid Square both sides [H+] 2 = Ka × Macid (1.5 × 10-4 )2 = 1.8 × 10-5 × Macid (1.5 × 10-4 )2 2.25 × 10-8 -3 ⇒ Macid = –––––––––– = ––––––––– = 1.25 ×10 mol/L 1.8 ×10-5 1.8 ×10-5 pH = - log 10 [H+] = -log 10 (1.5 × 10-4 ) = 3.82 Answer: Macid = 1.25 ×10-3 mol/L pH = 3.82 W 18.12 5.5 g H3 BO3 / L Rel molecular mass H3 BO3 = 3(1) + 11 + 3(16) = 62 Mass in 1L 5.5 Number of moles of HNO3 / L = –––––––––––––––– = –––– = 0.089 Rel molecular mass 62 H3 BO3 → H+ + H2 BO3 1 mole → 1 mole ⇒ 0.089 mole → 0.089 mole pH = - log 10 [H+] = - log 10 (0.089) = 1.05 Answer: pH = 1.05 W18.13 0.1 M HX acid is 3.5 % dissociated i.e. 3.5 % of 0.1 mole 3.5 –––– × 0.1 = 3.5 × 10-3 mole of H+ ions are formed 100 Ka can be found by substituting into the formula: __________ [H+] = √ Ka × Macid Square both sides [H+] 2 = Ka × Macid (3.5 × 10-3 )2 = Ka × 0.1 -4 ⇒ K a = 1.225 × 10 Answer: Ka = 1.225 × 10-4 149 Chemistry Live! – Worked Solutions W 18.14 (ii) Hydrogen ion concentration can be found by substituting into the formula: _________ + [H ] = √ Ka × Macid ____________ = √ 8 ×10-3 × 0.01 _________ = √ 8 × 10-5 = 8.94 ×10-3 mol/L pH = - log 10 [H+] = -log 10 (8.94 ×10-3 ) = 2.05 Answer: pH = 2.05 W 18.17 (ii) Hydrogen ion concentration can be found by substituting into the formula: _________ [H+] = √Ka × Macid _____________ = √2 ×10-5 × 0.01 _______ = √2 ×10-7 = 4.47 ×10-4 mol/L pH = - log 10 [H+] = -log 10 (4.47 ×10-4 ) = 3.35 Answer: pH =3.35 W 18.20 pH = - log 10 [H+] = 2.7 log 10 [H+] = - 2.7 + ⇒ [H ] = antilog (- 2.7) = 2 × 10-3 mol/L HA → H+ + A1 mole → 1 mole -3 -3 ⇒ 2 × 10 mole → 2 × 10 mole ⇒ [HA] = 2 × 10-3 mol/L Ka of HX can be found by substituting into the formula: __________ + [H ] = √ Ka × Macid Square both sides [H+] 2 = Ka × Macid (2 × 10-3 )2 = Ka × 0.5 -6 ⇒ K a = 8 × 10 Answer: [HA] = 2 × 10-3 mol/L Ka = 8 × 10-6 150 Chemistry Live! – Worked Solutions Workbook Chapter 19 – Environmental Chemistry – Water W19.2 (e) Given:VCa = 50 cm3 MCa = ? nCa = 1 Ved = 18 cm3 Med = 0.01 M ned = 1 Ca2+ edta VCa × MCa –––––––––– nCa Ved × Med ––––––––– ned = 50 × MCa 18 × 0.01 ––––––––– = –––––––– 1 1 18 × 0.01 ⇒ MCa = ––––––––– 50 = 3.6 × 10-3 moles/L CaCO3 = 3.6 × 10-3 × 100 g/L CaCO3 (Mr CaCO3 = 100) = 0.36 g/L CaCO3 = 0.36 × 1000 mg/L CaCO3 = 360 mg/L CaCO3 = 360 p.p.m. CaCO3 Answer Total hardness of water = 360 p.p.m. W19.3 (c) (i) Total hardness Given:VCa = 50 cm3 MCa = ? nCa = 1 Ved = 11.5 cm3 Med = 0.01 M ned = 1 Ca2+ VCa × MCa ––––––––– nCa edta Ved × Med = –––––––––– ned 50 × MCa 11.5 × 0.01 ––––––––– = –––––––––– 1 1 11.5 × 0.01 ⇒ MCa = –––––––––– 50 = 2.3 × 10-3 moles/L CaCO3 = 2.3 × 10-3 × 100 g/L CaCO3 (Mr CaCO3 = 100) = 0.23 g/L CaCO3 = 0.23 × 1000 mg/L CaCO3 = 230 mg/L CaCO3 = 230 p.p.m. CaCO3 151 Chemistry Live! – Worked Solutions (ii) Permanent Hardness, i.e. hardness which is not removed on boiling Given:Ca2+ edta VCa = 50 cm3 MCa = ? VCa × MCa Ved × Med nCa = 1 ––––––––– = –––––––––– Ved = 6.5 cm3 nCa ned Med = 0.01 M ned = 1 50 × MCa 6.5 × 0.01 –––––––– = ––––––––– 1 1 6.5 × 0.01 ⇒ MCa = ––––––––– 50 = 1.3 × 10-3 moles/L CaCO3 = 1.3 × 10-3 × 100 CaCO3 (Mr CaCO3 = 100) = 0.13 g/L CaCO3 = 0.13 × 1000 mg/L CaCO3 = 130 mg/L CaCO3 = 130 p.p.m. CaCO3 (iii) Temporary hardness, i.e. hardness which is removed on boiling. Temporary hardness = Total hardness – Permanent hardness = 230 –130 = 100 p.p.m. Answer: (i) Total hardness of water = 230 p.p.m. (ii) Permanent hardness of water = 130 p.p.m. (iii) Temporary hardness of water = 100 p.p.m. 152 Chemistry Live! – Worked Solutions W19.4 (iv) Given: VCa = 50 cm3 MCa = ? nCa = 1 Ved = 15 cm3 Med = 0.01 M ned = 1 Ca2+ edta VCa × MCa ––––––––– nCa Ved × Med ––––––––– ned = 50 × MCa ––––––––– = 1 15 × 0.01 ––––––––– 1 15 × 0.01 ⇒ MCa = –––––––– 50 = 3 × 10-3 moles/L CaCO3 = 3 × 10-3 × 100 g/L CaCO3 (Mr CaCO3 = 100) = 0. 3 g/L CaCO3 = 0.3 × 1000 mg/L CaCO3 = 300 mg/L CaCO3 = 300 p.p.m. CaCO3 Answer: Total hardness of water = 300 p.p.m. W19.5 (iv) Given:VCa = 50 cm3 MCa = ? nCa = 1 Ved = 9.5 cm3 Med = 0.01 M ned = 1 Ca2+ edta VCa × MCa ––––––––– nCa Ved × Med ––––––––– ned 50 × MCa –––––––– = 1 = 9.5 × 0.01 –––––––––– 1 9.5 × 0.01 ⇒ MCa = ––––––––– 50 = 1.9 × 10-3 moles/L = 1.9 × 10-3 × 40 g/L Ca2+ = 0.076 g/L Ca2+ …………. (a) = 1.9 × 10-3 × 100 g/L CaCO3 = 0.19 g/L CaCO3 = 0.19 × 1000 mg/L = 190 mg/L = 190 p.p.m. CaCO3 ………(b) Answer (a) Total hardness of water = 0.076 g of Ca2+/L (b) Total hardness of water = 190 p.p.m. CaCO3 153 Chemistry Live! – Worked Solutions W19.6 Total suspended solids = 1.47 g / 750 cm3 4 = 1.47 × ––– g/L 3 4 = 1.47 × ––– × 1,000 mg/L 3 = 1960 p.p.m. Total dissolved solids = 0.73 g / 200 cm3 = 0.73 × 5 g/L = 0.73 × 5 × 1,000 mg/L = 3650 p.p.m. Answer: Total suspended solids = 1960 p.p.m. Total dissolved solids = 3650 p.p.m. W19.8 Given:Vo = 200 cm3 Mo = ? no = 1 Vr = 22.7 cm3 Mr = 0.01 M nr = 4 S2 O3 2- O2 Vo × Mo –––––––– no = Vr × Mr –––––––– nr 200 × Mo –––––––– = 1 22.7 × 0.01 –––––––––– 4 22.7 × 0.01 ⇒ Mo = –––––––––––– 4 × 200 = = = = = = 154 2.8375 × 10-4 moles/L 2.8375 × 10-4 × 32 g/L (Rel molecular mass O2 =32) 9.08 × 10-3 g/L 9.08 × 10-3 × 1000 mg/L 9.08 mg/L 9.08 p.p.m. Chemistry Live! – Worked Solutions After 5 days Given: Vo = 200 cm3 Mo = ? no = 1 Vr = 4.8 cm3 Mr = 0.01 M nr = 4 S2 O3 2- O2 Vo × Mo ––––––––– = no Vr × Mr –––––––– nr 200 × Mo –––––––– = 1 4.8 × 0.01 –––––––––– 4 4.8 × 0.01 ⇒ Mo = –––––––– 4 × 200 = 6 × 10-5 moles/L = 6 × 10-5 × 32 g/L (Rel molecular mass O2 =32) = 1.92 × 10-3 g/L = 1.92 × 10-3 × 1000 mg/L = 1.92 mg/L = 1.92 p.p.m. B.O.D. in diluted sample = 9.08 –1.92 = 7.16 But since the original water sample was diluted ten times ⇒ B.O.D. of original water sample = 7.16 × 10 = 71.6 p.p.m. Answer: B.O.D. = 71.6 p.p.m. 155 Chemistry Live! – Worked Solutions Workbook Chapter 21 – Fuels and Heats of Reaction W21.12 Mass of solution = 100 g = 0.1 kg Temperature rise = 21.1 – 14.3 = 6.8 °C Specific heat capacity = 4,060 J kg-1 K-1 Heat liberated = mass × specific heat capacity × temp. rise = 0.1 × 4,060 × 6.8 = 2,760.8 J volume × molarity 50 × 1 Number of moles of HCl neutralised = –––––––––––––––– = –––––– = 0.05 1000 1000 i.e. 0.05 mole HCl neutralised liberates 2,760.8 J 2,760.8 1 mole HCl neutralised liberates ––––––– = 55,216 J 0.05 Since for HCl, 1 mole of acid gives 1 mole of H+ ions ∴Heat of neutralisation = - 55.216 k J mol-1 i.e. HCl + NaOH → NaCl + H2 O ∆H = - 55.216 k J mol-1 Answer: Heat of neutralisation = - 55.216 k J mol-1 W21.13 Mass of solution = 100 g = 0.1 kg Temperature rise = 13 °C Specific heat capacity = 4,200 J kg-1 K-1 Heat liberated = mass × specific heat capacity × temp. rise = 0.1 × 4,200 × 13 = 5,460 J volume × molarity 50 × 2 Number of moles of HNO3 neutralised = –––––––––––––––– = –––––– = 0.1 1000 1000 i.e. 0.1 mole HNO3 neutralised liberates 5,460 J ⇒ 5,460 1 mole HNO3 neutralised liberates –––––– = 54,600 J 0.1 Since for HNO3 , 1 mole of acid gives 1 mole of H+ ions ∴Heat of neutralisation = - 54.6 k J mol-1 HNO3 + KOH → KNO3 + H2 O Answer: Heat of neutralisation = - 54.6 k J mol-1 156 Chemistry Live! – Worked Solutions W21.14 Required Equation:- CH4 (g) + 4Cl2 (g) → CCl4 (l) + 4HCl (g) (a) reversed (b) (c) × 4 CH4 (g) → C(s) + 2H2 (g) C(s) + 2Cl2 (g) → CCl4 (l) 2H2 (g) + 2Cl2 (g) → 4HCl (g) ∆H =? ∆H = 74.9 kJ mol-1 ∆H = -139 kJ mol-1 ∆H = -369.2 kJ mol-1 CH4 (g) + C(s) + 2Cl2 (g) + 2H2 (g) + 2Cl2 (g) → C(s) + 2H2 (g) + CCl4 (l) + 4HCl (g) i.e. CH4 (g) + 4Cl2 (g) → CCl4 (l) + 4HCl (g) ∆H = -433.3 kJ mol-1 Answer: ∆H = -433.3 kJ mol-1 W21.15 Required Equation: CH3 OH (l) + 1½O (c) reversed (b) × 2 (a) 2 (g) → CO2 (g) + 2H2 O(l) CH3 OH (l) → C(s) + 2H2 (g) + O ½ 2H2 (g) + O2 (g) → 2H2 O(l) C(s) + O2 (g) → CO2 (g) ∆H = 250 kJ mol-1 ∆H = -572 kJ mol-1 ∆H = -394 kJ mol-1 2 (g) CH3 OH (l) + 2H2 (g) + O2 (g) + C(s) + O2 (g) → C(s) + 2H2 (g) + O ½ i.e. CH3 OH (l) + 1½O 2 (g) → CO2 (g) + 2H2 O(l) ∆H =? 2 (g) + 2H2 O(l) + CO2 (g) ∆H = -716 kJ mol-1 Answer: ∆H = -716 kJ mol-1 W21.16 Required Equation:- 2CH4 (g) + O2 (g) →2CH3 OH(l) (a) × 2 (c) (b) × 2 ∆H =? 2CH4 (g) + 2H2 O (g) → 2CO (g) + 6H2 (g) ∆H = 412 kJ mol-1 2H2 (g) + O2 (g) → 2H2 O (l) ∆H = -434 kJ mol-1 4H2 (g) + 2CO (g) → 2CH3 OH (g) ∆H = -256 kJ mol-1 2CH4 (g) + 2H2 O (g) + 2H2 (g) + O 2 (g) + 4H2 (g) + 2CO (g) → 2CO (g) + 6H2 (g) +2H2 O (l) + 2CH3 OH (g) i.e 2CH4 (g) + O2 (g) → 2CH3 OH(l) ∆H = -278 kJ mol-1 Answer: ∆H = -278 kJ mol-1 W21.17 Required Equation: C (s) + 2H2 (g) → CH4 (g) ∆H =? (b) × 2 (c) (a) reversed ∆H = -571.6 kJ mol-1 ∆H = -393.5 kJ mol-1 ∆H = 890.4 kJ mol-1 2H2 (g) + O2 (g) → 2H2 O (l) C (s) + O2 (g) → CO2 (g) CO2 (g) + 2H2 O (l) → CH4 (g) + 2O2 (g) 2H2 (g) + O2 (g) + C (s) + O2 (g) + CO2 (g) + 2H2 O (l) → 2H2 O (l) + CO2 (g) + CH4 (g) + 2O2 (g) i.e. C (s) + 2H2 (g) → CH4 (g) ∆H = -74.7 kJ mol-1 Answer: ∆H = -74.7 kJ mol-1 157 Chemistry Live! – Worked Solutions W21.18 Required Equation:- 3C (s) + 4H2 (g) → C3 H8 (g) (b) × 3 (c) × 4 (a) reversed ∆H =? 3C (s) + 3O2 (g) → 3CO2 (g) ∆H = -1,182 kJ mol-1 4H2 (g) + 2O2 (g) → 4H2 O (l) ∆H = -1,144 kJ mol-1 3CO2 (g) + 4H2 O (l) → C3 H8 (g) + 5O2 (g) ∆H = 2,220 kJ mol-1 3C (s) + 3O2 (g) + 4H2 (g) + 2O2 (g) +3CO2 (g) + 4H2 O (l) → 3CO2 (g) + 4H2 O (l) + C 3 H8 (g) + 5O2 (g) i.e. 3C (s) + 4H2 (g) → C3 H8 (g) ∆H = -106 kJ mol-1 Answer: ∆H = -106 kJ mol-1 W21.19 Required Equation:- 2C (s) + H2 (g) → C2 H2 (g) ∆H =? (b) × 2 2C (s) + 2O2 (g) → 2CO2 (g) ∆H = -788 kJ mol-1 (c) H2 (g) + ½O2 (g) → H2 O (l) ∆H = -286 kJ mol-1 (a) reversed 2CO2 (g) + H2 O (l) → C2 H2 (g) + 2½O 2 (g) ∆H = 1,299 kJ mol-1 2C (s) + 2O2 (g) + H2 (g) + O ½ i.e. 2 (g) + 2CO2 (g) + H2 O (l) → 2CO2 (g) + H2 O (l) + C2 H2 (g) + 2½O 2C (s) + H2 (g) → C2 H2 (g) ∆H = 225 kJ mol -1 Answer: ∆H = 225 kJ mol-1 W21.20 Required Equation:- N ½ (a) reversed × ¼ N ½ (b) × 1½ 1½H N ½ 2 (g) i.e. 2 (g) 2 (g) 2 (g) → NH3 (g) ∆H =? + 1½H 2 O (l) → NH3 (g) + ¾O O 2 (g) → 1½H 2 O (l) 2 (g) + ¾ 2 (g) + 1½H 2 O (l) +1½H N ½ + 1½H + 1½H 2 (g) 2 (g) + ¾O 2 (g) 2 (g) → NH3 (g) + ¾O → NH3 (g) ∆H = 317 kJ mol-1 ∆H = -428.7 kJ mol-1 2 (g) +1½H 2 O (l) ∆H = -111.7 kJ mol-1 Answer: ∆H = -111.7 kJ mol-1 W21.21 Required Equation:- Ca (s) +C (s) + 1½O (a) × ½ (b) 2 (g) ∆H =? ∆H = -320 kJ mol-1 ∆H = -393 kJ mol-1 + CO2 + C (s) + O 2 (g) → CaCO3 (s) + CO2 (g) i.e. Ca (s) +C (s) + 1½O 2 (g) → CaCO3 (s) Answer: ∆H = -713 kJ mol-1 158 → CaCO3 (s) Ca (s) + O ½ 2 (g) + CO2 → CaCO3 (s) C (s) + O2 (g) → CO2 (g) _________________ Ca (s) + O ½ 2 (g) ∆H = -713 kJ mol-1 2 (g Chemistry Live! – Worked Solutions W21.22 Required Equation:- C2 H2 (g) + HCN (g) → C3 H3 N (g) ∆H =? Given (a) 2C (s) + H2 (g) → C2 H2 (g) ∆H = 233 kJ mol-1 (b) H ½ 2 (g) + C (s) + N ½ 2 (g) → HCN (g) ∆H = 114.5 kJ mol-1 (c) 3C (s) + 1½H 2 (g) + N ½ 2 (g) → C3 H3 N (g) ∆H = 194.5 kJ mol-1 (a) reversed (b) reversed (c) C2 H2 (g) → 2C (s) + H2 (g) ∆H = -233 kJ molHCN (g→ H ½ 2 (g) + C (s) + N ½ 2 (g) ∆H = -114.5 kJ mol-1 3C (s) + 1½H 2 (g) + N ½ 2 (g) → C3 H3 N (g) ∆H = 194.5 kJ mol-1 C2 H2 (g) +HCN (g) + 3C (s) + 1½H i.e 2 (g) +N ½ 2 (g) → 2C (s) + H2 (g) + H ½ C2 H2 (g) + HCN (g) → C3 H3 N (g) 2 (g) + C (s) + N ½ 2 (g) +C3 H3 N (g) ∆H = -153 kJ mol-1 Answer: ∆H = -153 kJ mol-1 W21.23 Required Equation:- H2 (g) + S (s) + 2O2 (g) → H2 SO4 (l) ∆H =? Given (a) H2 (g) + O ½ 2 (g) → H2 O (l) ∆H = -286 kJ mol-1 (b) S (s) + O2 (g) → SO2 (g) ∆H = -297 kJ mol-1 (c) 2SO2 (g) + O 2 (g) → 2SO3 (g) ∆H = -196 kJ mol-1 (d) SO3 (g) + H2 O (l) → H2 SO4 (l) ∆H = -133 kJ mol-1 (a) (b) (c) × ½ (d) H2 (g) + O ½ 2 (g) → H2 O (l) S (s) + O2 (g) → SO2 (g) SO2 (g) + O ½ 2 (g) → SO3 (g) SO3 (g) + H2 O (l) → H2 SO4 (l) ∆H = -286 kJ mol-1 ∆H = -297 kJ mol-1 ∆H = -98 kJ mol-1 ∆H = -133 kJ mol-1 H2 (g) + O ½ 2 (g) + S (s) + O2 (g) + SO2 (g) + O ½ 2 (g) + SO3 (g) + H2 O (l) → H2 O (l) + SO2 (g) + SO3 (g) +H2 SO4 (l) i.e. H2 (g) + S (s) + 2O2 (g) → H2 SO4 (l) ∆H = -814 kJ mol-1 Answer: ∆H = -814 kJ mol-1 159 Chemistry Live! – Worked Solutions Chapter 24 –Stoichiometry II W24.1 Relative molecular mass FeS2 = 56 + 2(32) = 120 Relative molecular mass SO2 = 32 + 2(16) = 64 Iron pyrites is the limiting reagent as oxygen is in excess. Mass 5000 Number of moles of iron pyrites = –––––––––––––––– = –––––– = 416.67 Rel molecular mass 12 4FeS2 + 11O2 → 2Fe2 O3 + 8SO2 4 moles → 8 moles ⇒ 416.67 moles → 416.67 × 2 moles = 833.34 moles = 833.34 × 64 = 53,333.76 g i.e. the theoretical yield of SO2 is 53,333.76 g Actual yield of product Percentage yield = –––––––––––––––––––––––– Theoretical yield of product × 100 2725 = ––––––––– × 100 53,333.76 = 5.11% Answer : Percentage yield of sulphur dioxide is 5.11%. W24.2 Relative molecular mass NH4 Cl = 14 + 4(1) + 35.5 = 53.5 Relative molecular mass Ca(OH)2 = 40 + 2(17) = 74 Relative molecular mass NH3 = 14 + 3(1) = 17 Mass 20 Number of moles of ammonium chloride = ––––––––––––––––– = ––––– = 0.37 Rel molecular mass 53.5 Mass 20 Number of moles of calcium hydroxide = ––––––––––––––––– = –––– = 0.27 Rel molecular mass 74 2NH4 Cl + Ca(OH)2 → 2NH3 + CaCl2 + 2H2 O 2 moles 1 mole ⇒ 0.37 moles 0.37 moles 2 = 0.185 moles 160 Chemistry Live! – Worked Solutions 0.185 moles of calcium hydroxide would react with 0.37 moles of ammonium chloride. However, there is 0.27 moles of calcium hydroxide present, i.e. the calcium hydroxide is present in excess. Therefore the ammonium chloride is the limiting reactant, so we calculate the percentage yield of ammonia on the amount of ammonium chloride present. 2NH4 Cl + Ca(OH)2 → 2NH3 + CaCl2 + 2H2 O 2 moles → 2 moles ⇒ 0.37 moles → 0.37 moles = 0.37 × 17 = 6.29 g i.e. the theoretical yield of ammonia is 6.29 g ⇒ Maximum mass of ammonia produced = 6 g (to nearest gram) Answer: The maximum mass of ammonia produced in the reaction is 6 g. W24.3 Assume ethanol is the limiting reagent. Relative molecular mass C2 H5 OH = 2(12) + 5(1) + 16 + 1 = 46 Relative molecular mass CH3 COOH = 12 + 3(1) +12 +2(16) +1 = 60 Mass 24 Number of moles of ethanol = –––––––––––––––– = –––– = 0.52 Rel molecular mass 46 3C2 H5 OH + 2Cr2 O7 2- + 16H+ → 4Cr3+ + 3CH3 COOH + 11H2 O 3 moles → 3 moles ⇒ 0.52 moles → 0.52 moles = 0.52 × 60 = 31.2 g i.e. the theoretical yield of ethanoic acid is 31.2 g Percentage yield = Actual mass yield of product ––––––––––––––––––––––––– × Theoretical yield of product 100 28.5 = ––––– × 100 31.2 = 91.35% Answer : Percentage yield of ethanoic acid is 91% (to nearest whole number) 161 Chemistry Live! – Worked Solutions W24.4 (i) X = Ethanol (C2 H5 OH) Y = Propan-2-ol (C3 H5 OH) (ii) Relative molecular mass Na2 Cr2 O7 .2H2 O = 2(23) + 2(52) + 7(16) + 2(18) = 298 Relative molecular mass CH3 CHO = 12 + 3(1) + 12 + 1+ 16 = 44 Relative molecular mass CH3 COCH3 = 12 + 3(1) + 12 + 16 + 12 + 3(1) = 58 Mass 11.92 Number of moles of sodium dichromate = ––––––––––––––––– = ––––– = 0.04 Rel molecular mass 298 Sodium dichromate is the limiting reactant in both reactions, so we calculate the percentage yields of ethanal and propanone on the amount of sodium dichromate present. Group A Reaction 3C2 H5 OH + Cr2 O7 2- + 8H+ → 3CH3 CHO + 2Cr3+ + 7H2 O 1 mole → 3 moles ⇒ 0.04 mole → 0.04 × 3 mole = 0.12 mole = 0.12 × 44 = 5.28 g i.e. the theoretical yield of ethanal is 5.28 g Actual yield of product Percentage yield of Ethanal = ––––––––––––––––––––––– Theoretical yield of product 2.75 = ––––– × 100 5.28 = 52% (to nearest whole number) 162 × 100 Chemistry Live! – Worked Solutions Group B Reaction 3 C3 H5 OH + Cr2 O7 2- + 8H+ → 3CH3 COCH3 + 2Cr3+ + 7H2 O 1 mole →3 moles ⇒ 0.04moles → 0.04 × 3 moles = 0.12 moles = 0.12 × 58 = 6.96 g i.e. the theoretical yield of propanone is 6.96 g Actual yield of product –––––––––––––––––––––––– × 100 Theoretical yield of product Percentage yield of propanone = 5.15 = × 100 6.96 = 74% (to nearest whole number) Answer: (a) Percentage yield of ethanal is 52 %. (b) Percentage yield of propanone is 74 % W24.5 (i) 20% w/v solution of NaOH = 20 g of NaOH in 100 cm3 solution (a) 100 cm3 = 20 g ⇒ 30 30 cm3 = 20 × ----100 = 6 g of NaOH (b) Relative molecular mass NaOH = 23 + 16 + 1 = 40 Mass in 30 cm3 solution 6 Number of moles of NaOH = = = 0.15 in 30 cm3 solution Rel molecular mass 40 (ii) Rel molecular mass CH3 COOC2 H5 = 12 + 3(1) + 12 + 2(16) + 2(12) + 5(1) = 88 Mass of ethyl ethanoate = density × volume 0.9 × 6.6 5.94 mass 5.94 Number of moles of ethyl ethanoate = = = 0.0675 Rel molecular mass 88 Number of moles of NaOH = 0.15 163 Chemistry Live! – Worked Solutions CH3 COOC2 H5 1 mole ⇒ 0.0675 mole + NaOH → CH3 COOH + C2 H5 OH 1 mole 0.0675 mole 0.0675 mole of sodium hydroxide would react with 0.0675 molesof ethyl ethanoate. However, there is 0.15 mole of sodium hydroxide present, i.e. the sodium hydroxide is present in excess. (iii) Relative molecular mass CH3 COOH = 12 + 3(1) +12 +2(16) +1 = 60 The ethyl ethanoate is the limiting reactant, so we calculate the percentage yield of ethanoic acid on the amount of ethyl ethanoate present. CH3 COOC2 H5 + NaOH → CH3 COOH + C2 H5 OH 1 mole → 1 mole ⇒ 0.0675 mole → 0.0675 mole = 0.0675 × 60 = 4.05 g i.e. the theoretical yield of ethanoic acid is 4.05 g Percentage yield of ethanoic acid = Actual yield of product Theoretical yield of product × 3.1 = × 100 4.05 = 76.54% Answer: (i) There are (a) 6 g and (b) 0.15 moles of NaOH in 30 cm3 solution (ii) The sodium hydroxide is present in excess. (iii) Percentage yield of ethanoic acid is 76.54% 164 100
