CHAPTER 11 SOLUTIONS MANUAL Stoichiometry Section 11.1 Defining Stoichiometry pages 368–372 Practice Problems pages 371–372 1. Interpret the following balanced chemical equa- tions in terms of particles, moles, and mass. Show that the law of conservation of mass is observed. a. N2(g) 3H2(g) → 2NH3(g) 1 molecule N2 3 molecules H2 → 2 molecules NH3 1 mole N2 3 moles H2 → 2 moles NH3 Mass: N2: (2 mol)(14.007 g/mol) 28.014 g 3H2: (6 mol)(1.008 g/mol) 6.048 g Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 2NH3: (2 mol)(14.007 g/mol) (6 mol)(1.008 g/mol) 34.062 g c. 2Mg(s) O2(g) → 2MgO(s) 2 atoms Mg 1 molecule O2 0 2 formula units MgO 2 moles Mg 1 mole O2 → 2 moles MgO Mass: 2Mg: (2 mol)(24.305 g/mol) 48.610 g O2: (2 mol)(15.999 g/mol) 31.998 g 2MgO: (2 mol)(24.305 g/mol) (2 mol)(15.999 g/mol) 80.608 g 48.610 g Mg 31.998 g O2 → 80.608 g MgO 80.608 g reactants 80.608 g products 2. Challenge For each of the following, balance the chemical equation; interpret the equation in terms of particles, moles, and mass; and show that the law of conservation of mass is observed. a. ___Na(s) ___H2O(l) → ___NaOH(aq) ___H2(g) 28.014 g N2 6.048 g H2 0 34.062 g NH3 2Na(s) 2H2O(l) → 2NaOH(aq) 1H2(g) 34.062 g reactants 34.062 g products 2 atoms Na 2 molecules H2O → 2 formula units NaOH 1 molecule H2 b. HCl(aq) KOH(aq) → KCl(aq) H2O(l) 1 molecule HCl 1 formula unit KOH → 1 formula unit KCl 1 molecule H2O 1 mole HCl 1 mole KOH → 1 mole KCl 1 mole H2O Mass: HCl: (1 mol)(1.008 g/mol) (1 mol)(35.453 g/mol) 36.461 g KOH: (1 mol)(39.098 g/mol) (1 mol)(15.999 g/mol) (1 mol)(1.008 g/mol) 56.105 g 2 mol Na 2 mol H2O → 2 mol NaOH 1 mol H2 Mass: 2Na: (2 mol)(22.990 g/mol) 45.980 g 2H2O: (4 mol)(1.008 g/mol) (2 mol)(15.999 g/mol) 36.030 g 2NaOH: (2 mol)(22.990 g/mol) (2 mol)(15.999 g/mol) (2 mol)(1.008 g/mol) 79.994 g H2: (2 mol)(1.008 g/mol) 2.016 g KCl: (1 mol)(39.098 g/mol) (1 mol)(35.453 g/mol) 74.551 g 45.980 g Na 36.030 g H2O → 79.994 g NaOH 2.016 g H2 H2O: (2 mol)(1.008 g/mol) (1 mol)( 15.999 g/mol) 18.015 g 82.01 g reactants 82.01 g products 36.461 g HCl 56.105 g KOH → 74.551 g KCl 18.015 g H2O 92.566 g reactants 92.566 g products Solutions Manual Chemistry: Matter and Change • Chapter 11 209 11 SOLUTIONS MANUAL b. ___Zn(s) ___HNO3(aq) → ___Zn(NO3)2(aq) ___N2O(g) ___H2O(l) b. 3Fe(s) 4H2O(l) → Fe3O4(s) 4H2(g) 3 mol Fe 3 mol Fe 3 mol Fe __ __ _ 4 mol H2O 4Zn(s) 10HNO3(aq) → 4Zn(NO3)2(aq) 1N2O(g) 5H2O(l) 4 mol H2 1 mol Fe O 4 mol H 4 mol H O _ __ __ 2 4 atoms Zn 10 molecules HNO3 → 4 formula units Zn(NO3)2 1 molecule N2O 5 molecules H2O 4 mol Zn 10 mol HNO3 → 4 mol Zn(NO3)2 1 mol N2O 5 mol H2O Mass: 1 mol Fe3O4 3 2 3 mol Fe 3 mol Fe 4 3 mol Fe 1 mol Fe O 1 mol Fe O 4 mol H O __ __ __ 3 4 4 mol H2 3 4 2 4 mol H2O 4 mol H2 4 mol H O 4 mol H 4 mol H __ __ __ 2 2 1 mol Fe3O4 2 1 mol Fe3O4 4 mol H2O c. 2HgO(s) → 2Hg(l) O2(g) 4Zn: (4 mol)(65.39 g/mol) 261.56 g 1 mol O 1 mol O 2 mol HgO _ __ __ 10HNO3: (10 mol)(1.008 g/mol) (10 mol)(14.007 g/mol) (30 mol)(15.999 g/mol) 630.12 g 2 2 mol Hg 2 2 mol Hg 2 mol HgO 2 mol HgO 2 mol Hg __ 2 mol Hg __ _ 4Zn(NO3)2: (4 mol)(65.39 g/mol) (8 mol)(14.007 g/mol) (24 mol)(15.999 g/mol) 757.592 g 2 mol HgO 1 mol O2 1 mol O2 4. Challenge Balance the following equations, and determine the possible mole ratios. a. ZnO(s) HCl(aq) → ZnCl2(aq) H2O(l) N2O: (2 mol)(14.007 g/mol) (1 mol)(15.999 g/mol) 44.013 g ZnO(s) 2HCl(aq) → ZnCl2(aq) H2O(l) 5H2O: (10 mol)(1.008 g/mol) (5 mol)(15.999 g/mol) 90.075 g 1 mol ZnO __ 1 mol ZnO 1 mol ZnO __ __ 2 mol HCl 1 mol ZnCl2 1 mol H2O 261.56 g Zn 630.12 g HNO3 → 757.592 g Zn(NO3)2 44.013 g N2O 90.075 g H2O 2 mol HCl 2 mol HCl 2 mol HCl __ __ __ 891.68 g reactants 891.68 g products 1 mol ZnCl 1 mol ZnCl 1 mol ZnCl __ __ __ 3. Determine all possible mole ratios for the following balanced chemical equations. a. 4Al(s) 3O2(g) → 2Al2O3(s) 2 mol Al O 3 mol O 4 mol Al __ _ __ 2 2 3 mol O2 2 mol Al2O3 3 4 mol Al 2 mol Al O 3 mol O 4 mol Al _ __ __ 2 4 mol Al 2 3 mol O2 3 2 mol Al2O3 1 mol ZnO 1 mol ZnCl2 2 1 mol ZnO 1 mol H2O 2 2 mol HCl 2 1 mol H2O 1 mol H O __ 1 mol H O 1 mol H O __ __ 2 2 1 mol ZnO 2 2 mol HCl 1 mol ZnCl2 b. butane (C4H10) oxygen → carbon dioxide water 2C4H10(g) 13O2(g) 0 8CO2(g) 10H2O(l) 2 mol C H 2 mol C H 2 mol C H __ __ __ 4 10 13 mol O2 4 10 8 mol CO2 4 10 10 mol H2O 8 mol CO 10 mol H O 13 mol O __ __ __ 2 2 mol C4H10 2 2 mol C4H10 2 2 mol C4H10 10 mol H O _ 8 mol CO 10 mol H O __ __ 2 2 13 mol O2 2 8 mol CO2 13 mol O2 8 mol CO 13 mol O 13 mol O __ __ _ 2 10 mol H2O 210 Chemistry: Matter and Change • Chapter 11 2 10 mol H2O 2 8 mol CO2 Solutions Manual Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. CHAPTER CHAPTER 11 Section 11.1 Assessment page 372 5. Compare the mass of the reactants and the mass of the products in a chemical reaction, and explain how these masses are related. SOLUTIONS MANUAL 10. Model Write the mole ratios for the reaction of hydrogen gas and oxygen gas, 2H2(g) O2(g) → 2H2O. Make a sketch of six hydrogen molecules reacting with the correct number of oxygen molecules. Show the water molecules produced. The coefficients in the balanced equation indicate the molar relationship between each pair of reactants and products. The masses of reactants and products are equal. 6. State how many mole ratios can be written for a chemical reaction involving three substances. n 3, thus (n)(n 1) (3)(2) 6 mole ratios 7. Categorize the ways in which a balanced chemical equation can be interpreted. particles (atoms, molecules, formula units), moles, and mass 8. Apply The general form of a chemical reac- tion is xA yB → zAB. In the equation, A and B are elements and x, y, and z are coefficients. State the mole ratios for this reaction. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. xA/yB and xA/zAB 6H2 3O2 6H2O 2H2/O2 and 2H2/2H2O O2/2H2 and O2/2H2O 2H2O/2H2 and 2H2O/O2 Sketches should show six hydrogen atoms combining with three oxygen atoms to form six water molecules. yB/xA and yB/zAB zAB/xA and zAB/yB 9. Apply Hydrogen peroxide (H2O2) decomposes to produce water and oxygen. Write a balanced chemical equation for this reaction, and determine the possible mole ratios. 2H2O2 → 2H2O O2 2 mol H2O2/2 mol H2O, 2 mol H2O2/1 mol O2, 2 mol H2O/2 mol H2O2, 2 mol H2O/1 mol O2, 1 mol O2/2 mol H2O2, 1 mol O2/2 mol H2O Section 11.2 Stoichiometric Calculations pages 373–378 Practice Problems pages 375–377 11. Methane and sulfur react to produce carbon disulfide (CS2), a liquid often used in the production of cellophane. ___CH4(g) ___S8(s) → ___CS2(l) ___H2S(g) a. Balance the equation. 2CH4(g) S8(s) → 2CS2(l) 4H2S(g) b. Calculate the moles of CS2 produced when 1.50 moles of S8 is used. 1.50 mol S8 Solutions Manual 2 mol CS _ 3.00 mol CS 2 1 mol S8 Chemistry: Matter and Change • Chapter 11 2 211 11 SOLUTIONS MANUAL c. How many moles of H2S are produced? 1.50 mol S8 4 mol H S _ 6.00 mol H S 2 2 1 mol S8 12. Challenge Sulfuric acid (H2SO4) is formed when sulfur dioxide (SO2) reacts with oxygen and water. a. Write the balanced chemical equation for the reaction. 2SO2(g) O2(g) 2H2O(l) → 2H2SO4(aq) b. How many moles of H2SO4 are produced from 12.5 moles of SO2? 12.5 mol SO2 __ elements sodium and chlorine by means of electrical energy, as shown below. How much chlorine gas, in grams, is obtained from the process? Na 2 2 1 mol Cl2 2 1 mol C __ 1.25 mol C 1 mol TiO2 Step 2: Make mole → mass conversion. 1.25 mol C 12.011 g C __ 15.0 g C 1 mol C c. What is the mass of all of the products formed by reaction with 1.25 mol of TiO2? Cl2 ? g Calculate the mass to TiO2 used. Step 1: Balance the chemical equation. 1.25 mol TiO2 2NaCl(s) → 2Na(s) Cl2(g) 79.865 g TiO __ 99.8 g TiO 2 1 mol TiO2 2 Calculate the total mass of the reactants. Step 2: Make mole → mole conversion. 1 mol Cl __ 1.25 mol Cl 99.8 g 177 g 15.0 g 292 g 2 2 2 mol NaCl Step 3: Make mole → mass conversion. 212 2 1 mol TiO2 70.90 g Cl __ 177 g Cl 1.25 mol TiO2 13. Sodium chloride is decomposed into the 1.25 mol Cl2 2 mol Cl __ 2.50 mol Cl Step 1: Make mole → mole conversion. 2 mol SO2 6.25 mol O2 needed 2.50 mol NaCl 1.25 mol TiO2 1.25 mol of TiO2? 2 2.50 mol Step 1: Make mole → mole conversion. b. What mass of C is needed to react with 1 mol O _ NaCl TiO2(s) C(s) 2Cl2(g) → TiCl4(s) CO2(g) a. What mass of Cl2 gas is needed to react with 1.25 mol of TiO2? 2.50 mol Cl2 c. How many moles of O2 are needed? Electric energy in many alloys because it is extremely strong and lightweight. Titanium tetrachloride (TiCl4) is extracted from titanium oxide (TiO2) using chlorine and coke (carbon). Step 2: Make mole → mass conversion. 2 mol H2SO4 2 mol SO2 12.5 mol H2SO4 produced 12.5 mol SO2 14. Challenge Titanium is a transition metal used 70.9 g Cl _ 88.6 g Cl Because mass is conserved, the mass of the products must equal the mass of reactants. mass of products 292 g 2 1 mol Cl2 2 Chemistry: Matter and Change • Chapter 11 Solutions Manual Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. CHAPTER CHAPTER 11 SOLUTIONS MANUAL Step 4: Make mole → mass conversion. 15. One of the reactions used to inflate automobile air bags involves sodium azide (NaN3): 2NaN3(s) → 2Na(s) 3N2(g). Determine the mass of N2 produced from the decomposition of NaN3 shown below. 0.0390 mol H2SO4 3.83 g H2SO4 98.09 g H SO __ 2 4 1 mol H2SO4 Section 11.2 Assessment N2 gas page 378 17. Explain why a balanced chemical equation is needed to solve a stoichiometric problem. The coefficients in the balanced equation indicate the molar relationship between each pair of reactants and products. 100.0 g NaN3 → ? g N2(g) 2NaN3(s) → 2Na(s) 3N2(g) Step 1: Make mass → mole conversion. 100.0 g NaN3 18. List the four steps used in solving stoichio- __ 1.538 mol NaN 1 mol NaN3 3 65.02 g NaN3 Step 2: Make mole → mole conversion. 1.538 mol NaN3 3 mol N __ 2.307 mol N 2 2 2 mol NaN3 Step 3: Make mole → mass conversion. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 2.307 mol N2 28.02 g N __ 64.64 g N 2 16. Challenge In the formation of acid rain, sulfur dioxide (SO2) reacts with oxygen and water in the air to form sulfuric acid (H2SO4). Write the balanced chemical equation for the reaction. If 2.50 g of SO2 reacts with excess oxygen and water, how much H2SO4, in grams, is produced? Step 1: Balance the chemical equation. 2SO2(g) O2(g) 2H2O(l) 0 2H2SO4(aq) Step 2: Make mass → mole conversion. 2.50 g SO2 1. Balance the equation. 2. Convert the mass of the known substance to moles of known substance. 3. Use the mole ratio to convert from moles of the known to moles of the unknown. 4. Convert moles of unknown to mass of the unknown. 2 1 mol N2 metric problems. 1 mol SO __ 0.0390 mol SO 2 19. Describe how a mole ratio is correctly expressed when it is used to solve a stoichiometric problem. moles of unknown/moles of known 20. Apply How can you determine the mass of liquid bromine (Br2) needed to react completely with a given mass of magnesium? Write a balanced equation. Convert the given mass of magnesium to moles. Use the mole ratio from the balanced equation to convert moles of magnesium to moles of bromine. Convert from moles of bromine to mass of bromine. 2 64.07 g SO2 Step 3: Make mole → mole conversion. 0.0390 mol SO2 2 mol H SO __ 2 4 2 mol SO2 0.0390 mol H2SO4 Solutions Manual Chemistry: Matter and Change • Chapter 11 213 11 SOLUTIONS MANUAL 21. Calculate Hydrogen reacts with excess nitrogen as follows: 0.6261 mol Fe O 1 mol Fe O __ compared to __ 2 If 2.70 g of H2 reacts, how many grams of NH3 is formed? ( __ ) 1.34 mol H2 1 mol 1.34 mol H2 2.016 g H2 (_) ( __ ) 2 mol NH3 3 mol H2 (0.893 mol NH3) 3 2 4.350 mol Na N2(g) 3H2(g) → 2NH3(g) (2.70 g H2) Make mole ratio comparison. 0.893 mol NH3 17.031 g NH3 1 mol NH3 0.1439 compared to 0.1667 The actual ratio is less than the needed ratio, so iron(III) oxide is the limiting reactant. b. reactant in excess Sodium is the excess reactant. c. mass of solid iron produced 15.2 g NH3 22. Design a concept map for the following Make mole → mole conversion. 0.6261 mol Fe2O3 2 mol Fe __ 1 mol Fe2O3 reaction. 1.252 mol Fe CaCO3(s) 2HCl(aq) → CaCl2(aq) H2O(l) CO2(g) Make mole → mass conversion. The concept map should explain how to determine the mass of CaCl2 produced from a given mass of HCl. Concept maps will vary, but all should show the use of these conversion factors: the inverse of molar mass, the mole ratio, the molar mass. Section 11.3 Limiting Reactants pages 379–384 1.252 mol Fe 1 mol Fe the reaction is complete Make mole → mole conversion. 0.6261 mol Fe2O3 6 mol Na __ 1 mol Fe2O3 3.757 mol Na needed Make mole → mass conversion. 22.9 g Na _ 1 mol Na 86.37 g Na needed page 383 23. The reaction between solid sodium and iron(III) oxide is one in a series of reactions that inflates an automobile airbag: 6Na(s) Fe2O3(s) → 3Na2O(s) 2Fe(s). If 100.0 g of Na and 100.0 g of Fe2O3 are used in this reaction, determine the following. a. limiting reactant Make mass → mole conversion. 1 mol Na __ 4.350 mol Na 22.99 g Na 100.0 g Fe2O3 55.85 g Fe _ 69.92 g Fe d. mass of excess reactant that remains after 3.757 mol Na Practice Problems 100.0 g Na 3 6 mol Na 100.0 g Na given 86.37 g Na needed 13.6 g Na in excess 24. Challenge Photosynthesis reactions in green plants use carbon dioxide and water to produce glucose (C6H12O6) and oxygen. A plant has 88.0 g of carbon dioxide and 64.0 g of water available for photosynthesis. a. Write the balanced chemical equation for the reaction. 6CO2(g) 6H2O(l) 0 C6H12O6(aq) 6O2(g) 1 mol Fe O __ 2 3 159.7 g Fe2O3 0.6261 mol Fe2O3 214 Chemistry: Matter and Change • Chapter 11 Solutions Manual Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. CHAPTER 11 CHAPTER SOLUTIONS MANUAL Section 11.3 Assessment b. Determine the limiting reactant. page 384 Make mass → mole conversion. 88.0 g CO2 1 mol CO __ 2.00 mol CO 2 2 44.01 g CO2 1 mol H O 64.0 g H O __ 3.55 mol H O 25. Describe the reason why a reaction between two elements comes to an end. one of the reactants is used up 2 2 2 18.02 g H2O each reaction. a. Wood burns in a campfire. Make mole ratio comparison. 2.00 mol CO 6 mol CO __ compared to __ ; 2 2 3.55 mol H2O 6 mol H2O 26. Identify the limiting and the excess reactant in The wood limits. Oxygen is in excess. The fire will burn only while wood is present. 0.563 compared to 1.00 The actual ratio is less than the needed ratio, so carbon dioxide is the limiting reactant. b. Airborne sulfur reacts with the silver plating on a teapot to produce tarnish (silver sulfide). Silver is the limiting reactant. Sulfur is in excess. When a layer of tarnish covers the silver surface, it prevents the sulfur in the air from reacting. c. Determine the excess reactant. Water is the excess reactant. d. Determine the mass in excess. c. Baking powder in batter decomposes to Make mole → mole conversion. 2.00 mol CO2 __ 2.00 mol H O 6 mol H2O 2 6 mol CO2 Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Make mole → mass conversion. 2.00 mol H2O 18.02 g H O __ 64.0 g H2O given 36.0 g H2O needed 28.0 g H2O in excess e. Determine the mass of glucose produced. Make mole → mole conversion. 1 mol C H O __ 6 12 6 6 mol CO2 0.333 mol C6H12O6 Make mole 0 mass conversion. 0.333 mol C6H12O6 60.0 g C6H12O6 A decomposition reaction usually has only one reactant. The reaction is limited by the amount of baking powder present. 27. Analyze Tetraphosphorous trisulphide (P4S3) 2 1 mol H2O 36.0 g H2O needed 2.00 mol CO2 produce carbon dioxide. __ is used in the match heads of some matches. It is produced in the reaction 8P4 3S8 → 8P4S3. Determine which of the following statements are incorrect, and rewrite the incorrect statements to make them correct. a. 4 mol P4 reacts with 1.5 mol S8 to form 4 mol P4S3. correct b. Sulfur is the limiting reactant when 4 mol P4 and 4 mol S8 react. Phosphorus is the limiting reactant. 180.24 g C6H12O6 1 mol C6H12O6 c. 6 mol P4 reacts with 6 mol S8, forming 1320 g P4S3. correct Solutions Manual Chemistry: Matter and Change • Chapter 11 215 11 SOLUTIONS MANUAL Section 11.4 Percent Yield b. Determine the percent yield if 515.6 g of pages 385–388 product is recovered. Practice Problems % yield 28. Aluminum hydroxide (Al(OH)3) is often present in antacids to neutralize stomach acid (HCl). The reaction occurs as follows: Al(OH)3(s) 3HCl(aq) → AlCl3(aq) 3H2O(l). If 14.0 g of Al(OH)3 is present in an antacid tablet, determine the theoretical yield of AlCl3 produced when the tablet reacts with HCl. 1 mol Al(OH) __ determine the theoretical yield of silver. Make mass → mole conversion. Make mole → mole conversion. 20.0 g Cu __ 1 mol AlCl3 1 mol Al(OH)3 63.55 g Cu 0.315 mol Cu 133.3 g AlCl __ 23.9 g AlCl 2 mol Ag _ 0.630 mol Ag 1 mol Cu Make mole → mass conversion. 3 1 mol AlCl3 1 mol Cu __ 0.315 mol Cu Make mole → mole conversion. Make mole → mass conversion. 0.179 mol AlCl3 silver nitrate solution (AgNO3), silver crystals and copper(II) nitrate (Cu(NO3)2) solution form. a. Write the balanced chemical equation for the reaction. b. If a 20.0g sample of copper is used, 3 78.0 g Al(OH)3 0.179 mol Al(OH)3 0.179 mol AlCl3 30. Challenge When copper wire is placed into a Cu(s) 2AgNO3(aq) → 2Ag(s) Cu(NO3)2(aq) Make mass → mole conversion. 0.179 mol Al(OH)3 2 610.3 g ZnI2 84.48% yield of ZnI2 page 387 14.0 g Al(OH)3 515.6 g ZnI __ 100 3 0.630 mol Ag 23.9 g of AlCl3 is the theoretical yield. 29. Zinc reacts with iodine in a synthesis reaction: Zn I2 0 ZnI2. a. Determine the theoretical yield if 1.912 mol of zinc is used. 1 mol Ag 68.0 g of Ag is the theoretical yield. c. If 60.0 g of silver is recovered from the reaction, determine the percent yield of the reaction. % yield Write the balanced chemical equation. 107.9 g Ag __ 68.0 g Ag 60.0 g Ag _ 100 68.0 g Ag 88.2% yield of Ag Zn(s) I2(s) → ZnI2(s) Make mole → mole conversion. 1.912 mol Zn Section 11.4 Assessment 1 mol ZnI _ 1.912 mol ZnI 2 1 mol Zn 2 31. Identify which type of yield—theoretical Make mole → mass conversion. 1.912 mol ZnI2 __ 610.3 g ZnI 319.2 g ZnI2 1 mol ZnI2 2 610.3 g of ZnI2 is the theoretical yield. 216 page 388 Chemistry: Matter and Change • Chapter 11 yield, actual yield, or percent yield—is a measure of the efficiency of a chemical reaction. percent yield Solutions Manual Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. CHAPTER 11 CHAPTER SOLUTIONS MANUAL 32. List several reasons why the actual yield from a chemical reaction is not usually equal to the theoretical yield. Not all reactions go to completion. Some of the reactants or products stick to the surface of the container and are not massed or transferred. Other unexpected products form from competing reactions. 33. Explain how percent yield is calculated. divide the actual yield by the theoretical yield and multiply the quotient by 100 34. Apply In an experiment, you combine 83.77 g of iron with an excess of sulfur and then heat the mixture to obtain iron(III) sulfide. What is the theoretical yield, in grams, of iron(III) sulfide? ( __ ) Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 1.500 mol Fe 1 mol Fe 1.500 mol Fe 55.845 g Fe ( __ ) ( __ ) 1 mol Fe2S3 207.885 g Fe2S3 2 mol Fe 1 mol Fe2S3 155.9 g Fe2S3 pages 392–397 Section 11.1 Mastering Concepts 36. Why must a chemical equation be balanced before you can determine mole ratios? Mole ratios are determined by the coefficients in a balanced equation. If the equation is not balanced, the relationship between reactants and products cannot be determined. 37. What relationships can be determined from a balanced chemical equation? The relationships among particles, moles, and mass for all reactants and products. 2Fe(s) 3S(s) → Fe2S3(s) (83.77 g Fe) Chapter 11 Assessment 38. Explain why mole ratios are central to stoichiometric calculations. Mole ratios allow for the conversion from moles of one substance in a balanced chemical equation to moles of another substance in the same equation. 39. What is the mole ratio that can convert from moles of A to moles of B? 35. Calculate the percent yield of the reaction of 2Mg(s) O2(g) → 2MgO(s) 40. Why are coefficients used in mole ratios instead of subscripts? Reaction Data Mass of empty crucible 35.67 g Mass of crucible and Mg 38.06 g Mass of crucible and MgO (after heating) 39.15 g mass of Mg 38.06 g 35.67 g 2.39 g mass of MgO 39.15 g 33.67 g 3.48 g Theoretical yield: 2.39 g Mg moles B _ moles A magnesium with excess oxygen: 1 mol Mg __ 24.31 g Mg The coefficients in the balanced chemical equation show the numbers of representative particles involved in a reaction. Subscripts give the numbers of different kinds of atoms within a molecule or formula unit. 41. Explain how the conservation of mass allows you to interpret a balanced chemical equation in terms of mass. The mass of the reactants will always equal the mass of the products. 0.0983 mol Mg 0.983 mol Mg 40.31 g MgO 2 mol MgO __ __ 2 mol Mg 1 mol MgO 3.96 g MgO % yield 3.48 g MgO __ 100 3.96 g MgO 87.9% yield of MgO Solutions Manual Chemistry: Matter and Change • Chapter 11 217 11 CHAPTER SOLUTIONS MANUAL 42. When heated by a flame, ammonium dichro- mate decomposes, producing nitrogen gas, solid chromium(III) oxide, and water vapor. Mastering Problems 44. Interpret the following equation in terms of particles, moles, and mass. (NH4)2Cr2O7 → N2 Cr2O3 4H2O 4Al(s) 3O2(g) → 2Al2O3(s) Write the mole ratios for this reaction that relate ammonium chromate to the products. Particles: 4 atoms Al 3 molecules O2 → 2 formula units Al2O3 1 mol (NH ) Cr O 1 mol (NH ) Cr O __ __ Moles: 4 mol Al 3 mol O2 → 2 mol Al2O3; 4 2 2 7 4 2 1 mol N2 2 7 1 mol Cr2O3 1 mol (NH ) Cr O __ 4 2 2 Mass: 4Al 4 mol Al(26.982 g/mol) 107.93 g 7 4 mol H2O __ __ 1 mol N2 1 mol Cr2O3 1 mol (NH4)2Cr2O7 1 mol (NH4)2Cr2O7 4 mol H O __ 3O2 6 mol O(15.999 g/mol) 95.99 g 2Al2O3 4 mol Al(26.982 g/mol) 6 mol O(15.999 g/mol) 203.92 g 107.93 g Al 95.99 g O2 → 203.92 g Al2O3 2 1 mol (NH4)2Cr2O7 45. Smelting When tin(IV) oxide is heated with carbon in a process called smelting, the element tin can be extracted. SnO2(s) 2C(s) → Sn(l) 2CO(g) representing Element M and circles representing Element N. Write a balanced equation to represent the picture shown, using smallest whole-number ratios. Write mole ratios for this equation. Particles: 1 formula unit SnO2 2 atoms C → 1 atom Sn 2 molecules CO 2M2N → M4 N2 Mass: 2 mol M N __ 2 mol M N __ , , 2 1 mol M4 2 1 mol N2 1 mol M 1 mol M __ _ , , 4 4 Moles: 1 mol SnO2 2 mol C → 1 mol Sn 2 mol CO SnO2: 1 mol(118.710 g/mol) 2 mol (15.999 g/mol) 150.71 g 2C: 2 mol(12.011 g/mol) 24.02 g 1 mol N2 2 mol M2N Sn: 1 mol(118.710 g/mol) 118.71 g 1 mol N 1 mol N __ ,_ 2CO: 2 mol(12.011 g/mol) 2 mol (15.999 g/mol) 56.02 g 2 2 2 mol M2N 1 mol M4 218 Interpret the chemical equation in terms of particles, moles, and mass. Chemistry: Matter and Change • Chapter 11 150.71 g SnO2 24.02 g C → 118.71 g Sn 56.02 g CO Solutions Manual Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 43. Figure 11.10 depicts an equation with squares CHAPTER 11 46. When solid copper is added to nitric acid, 48. When aluminum is mixed with iron(III) oxide, copper(II) nitrate, nitrogen dioxide, and water are produced. Write the balanced chemical equation for the reaction. List six mole ratios for the reaction. iron metal and aluminum oxide are produced along with a large quantity of heat. What mole ratio would you use to determine moles of Fe if moles of Fe2O3 are known? Cu(s) 4HNO3(aq) → Cu(NO3)2(aq) 2NO2(g) 2H2O(l); answers should include any six of the following ratios: 1 mol Cu/4 mol HNO3, 1 mol Cu/1 mol Cu(NO3)2, 1 mol Cu/2 mol NO2, 1 mol Cu/2 mol H2O, 4 mol HNO3/1 mol Cu, 4 mol HNO3/1 mol Cu(NO3)2, 4 mol HNO3/2 mol NO2, 4 mol HNO3/2 mol H2O, 1 mol Cu(NO3)2/1 mol Cu, 1 mol Cu(NO3)2/4 mol HNO3, 1 mol Cu(NO3)2/2 mol NO2, 1 mol Cu(NO3)2/2 mol H2O, 2 mol NO2/1 mol Cu, 2 mol NO2/4 mol HNO3, 2 mol NO2/1 mol Cu(NO3)2, 2 mol NO2/2 mol H2O, 2 mol H2O/1 mol Cu, 2 mol H2O/4 mol HNO3, 2 mol H2O/1 mol Cu(NO3)2, 2 mol H2O/2 mol NO2 Fe2O3(s) 2Al(s) → 2Fe(s) Al2O3(s) heat 47. When hydrochloric acid solution reacts with lead(II) nitrate solution, lead(II) chloride precipitates and a solution of nitric acid is produced. a. Write the balanced chemical equation for the reaction. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. SOLUTIONS MANUAL 2HCl(aq) Pb(NO3)2(aq) → PbCl2(s) 2HNO3(aq) b. Interpret the equation in terms of molecules and formula units, moles, and mass. Particles: 2 molecules HCl 1 formula unit Pb(NO3)2 → 1 formula unit PbCl2 2 molecules HNO3 Moles: 2 mol HCl 1 mol Pb(NO3)2 → 1 mol PbCl2 2 mol HNO3; 2 mol Fe __ 1 mol Fe2O3 49. Solid silicon dioxide, often called silica, reacts with hydrofluoric acid (HF) solution to produce the gas silicon tetrafluoride and water. a. Write the balanced chemical equation for the reaction. SiO2(s) 4HF(aq) → SiF4(g) 2H2O(l) b. List three mole ratios, and explain how you would use them in stoichiometric calculations. Students may write any of 12 ratios. Examples might be the following. 4 mol HF/1 mol SiO2; used to find the amount of HF that will react with a known amount of SiO2; 1 mol SiF4/1 mol SiO2; used to find the amount of SiF4 that can be formed from a known amount of SiO2. 2 mol H2O/1 mol SiF4; used to find the amount of H2O that will be produced with the SiF4 50. Chrome The most important commercial ore of chromium is chromite (FeCr2O4). One of the steps in the process used to extract chromium from the ore is the reaction of chromite with coke (carbon) to produce ferrochrome (FeCr2). Mass: 2C(s) FeCr2O4(s) → FeCr2(s) 2CO2(g) 2HCl: 2 mol(1.008 g/mol) 2 mol (35.453 g/mol) 72.9 g What mole ratio would you use to convert from moles of chromite to moles of ferrochrome? Pb(NO3)2: 1 mol(207.2 g/mol) 2 mol (14.007 g/mol) 6 mol(15.999 g/mol) 331.2 g 1 mol FeCr __ 2 1 mol FeCr2O4 PbCl2: 1 mol(207.2 g/mol) 2 mol (35.453 g/mol) 278.1 g 2HNO3: 2 mol(1.008 g/mol) 2 mol (14.007 g/mol) 6 mol(15.999 g/mol) 126.0 g 72.9 g HCl 331.2 g Pb(NO3)2 → 278.1 g PbCl2 126.0 g HNO3 Solutions Manual Chemistry: Matter and Change • Chapter 11 219 11 SOLUTIONS MANUAL 51. Air Pollution The pollutant SO2 is removed from the air in a reaction that also involves calcium carbonate and oxygen. The products of this reaction are calcium sulfate and carbon dioxide. Determine the mole ratio you would use to convert moles of SO2 to moles of CaSO4. 2SO2 2CaCO3 O2 → 2CaSO4 2CO2 2 mol CaSO __ 4 Section 11.2 Mastering Concepts 54. What is the first step in all stoichiometric calculations? Write a balanced chemical equation for the reaction. 55. What information does a balanced equation 2 mol SO2 provide? 52. Two substances, W and X, react to form the products Y and Z. Table 11.2 shows the moles of the reactants and products involved when the reaction was carried out. Use the data to determine the coefficients that will balance the equation W X → Y Z. Reaction Data Moles of Reactants Moles of Products W X Y Z 0.90 0.30 0.60 1.20 Divide each molar quantity by 0.30 mol, the least common denominator: The balanced equation provides the relationship between reactants and products, and the coefficients in the equation are used to write mole ratios relating reactants and products. 56. On what law is stoichiometry based, and how do the calculations support this law? Stoichiometry is based on the law of conservation of mass. The calculations are used to determine the mass of reactants and products. Once found, the sum of reactants will equal the sum of products, verifying the law of conservation of mass. 57. How is molar mass used in some stoichiometric calculations? W: 0.90/0.30 3 Molar mass is a conversion factor for converting moles of a given substance to mass or mass of a given substance to moles. X: 0.30/0.30 1 Y: 0.60/0.30 2 Z: 1.20/0.30 4 58. What information must you have in order to calculate the mass of product formed in a chemical reaction? 3W X 0 2Y 4Z 53. Antacids Magnesium hydroxide is an ingre- dient in some antacids. Antacids react with excess hydrochloric acid in the stomach to relieve indigestion. You must have the balanced chemical equation and know the quantity of one substance in the reaction other than the product you are to determine. ___Mg(OH)2 ___HCl → ___ MgCl2 ___ H2O a. Balance the reaction of Mg(OH)2 with HCl. 1Mg(OH)2 2HCl → 1MgCl2 2H2O b. Write the mole ratio that would be used to determine the number of moles of MgCl2 produced when HCl reacts with Mg(OH)2. 1 mol MgCl __ 2 1 mol Mg(OH)2 220 or 1 mol MgCl __ 2 2 mol HCl Chemistry: Matter and Change • Chapter 11 Solutions Manual Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. CHAPTER CHAPTER 11 SOLUTIONS MANUAL 61. Welding If 5.50 mol of calcium carbide (CaC2) reacts with an excess of water, how many moles of acetylene (C2H2), a gas used in welding, will be produced? + CaC2(s) 2H2O(l) → Ca(OH)2(aq) C2H2(g) 59. Each box in Figure 11.11 represents the contents of a flask. One flask contains hydrogen sulfide, and the other contains oxygen. When the contents of the flasks are mixed, a reaction occurs and water vapor and sulfur are produced. In the figure, the red circles represent oxygen, the yellow circles represent sulfur, and blue circles represent hydrogen. a. Write the balanced chemical equation for the reaction. 2H2S(g) O2(g) → 2H2O(g) 2S(s) b. Using the same color code, sketch a representation of the flask after the reaction occurs. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Student sketches should show the formation of six water molecules (H2O) and six sulfur atoms (S). Mastering Problems 60. Ethanol (C2H5OH ), also known as grain alcohol, can be made from the fermentation of sugar (C6H12O6). The unbalanced chemical equation for the reaction is shown below. ___C6H12O6 → ___C2H5OH ___CO2 Balance the chemical equation and determine the mass of C2H5OH produced from 750 g of C6H12O6. C6H12O6 → 2C2H5OH 2CO2 ( 2 mol C H OH __ 8.4 mol C2H5OH 8.4 mol C2H5OH Solutions Manual ( 2 5 1 mol C6H12O6 46.07 g __ 1 mol C2H5OH 62. Antacid Fizz When an antacid tablet dissolves in water, the fizz is due to a reaction between sodium hydrogen carbonate (NaHCO3), also called sodium bicarbonate, and citric acid (H3C6H5O7). 3NaHCO3(aq) H3C6H5O7(aq) → 3CO2(g) 3H2O(l) Na3C6H5O7(aq) How many moles of Na3C6H5O7 can be produced if one tablet containing 0.0119 mol of NaHCO3 is dissolved? 0.0119 mol NaHCO3 (1 mol Na3C6H5O7/3 mol NaHCO3) 0.00397 mol 63. Esterification The process in which an organic acid and an alcohol that forms as ester and water is known as esterification. Ethyl butanoate (C3H7COOC2H5), an ester, is formed when the alcohol ethanol (C2H5OH) and butanoic acid (C3H7COOH) are heated in the presence of sulfuric acid. C2H5OH(l) C3H7COOH(l) → C3H7COOC2H5(l) H2O(l) Determine the mass of ethyl butanoate produced if 4.50 mol of ethanol is used. 1 mol C H COOC H __ 1 mol C H OH 116.18 g C H COOC H ___ 3 7 4.50 mol C2H5OH 2 5 2 5 750 g C6H12O6(180.16 g/mol) 4.2 mol C6H12O6 4.2 mol C6H12O6 The mole ratio of CaC2:C2H2 is 1:1; thus, 5.50 mol C2H2 will be produced from 5.50 mol CaC2. ) ) 3 7 2 5 1 mol C3H7COOC2H5 523 g C3H7COOC2H5 390 g C2H5OH Chemistry: Matter and Change • Chapter 11 221 11 SOLUTIONS MANUAL 64. Greenhouse Gas Carbon dioxide is a green- house gas that is linked to global warming. It is released into the atmosphere through the combustion of octane (C8H18) in gasoline. Write the balanced chemical equation for the combustion of octane and calculate the mass of octane needed to release 5.00 mol of CO2. 2C8H18(l) 25O2(g) 0 16CO2(g) 18H2O(l) 5.00 mol CO2 0.625 mol C8H18 __ 0.625 mol C H 2 mol C8H18 produced by a reaction between methane and chlorine. CH4(g) 3Cl2(g) 0 CHCl3(g) 3HCl(g) How much CH4 in grams is needed to produce 50.0 grams of CHCl3? 50.0 g CHCl3 8 18 16 mol CO2 114.28 g C H __ 71.4 g C H 8 18 1 mol C8H18 solution of lead(II) nitrate to produce a yellow precipitate of lead(II) chromate and a solution of potassium nitrate. a. Write the balanced chemical equation. K2CrO4(aq) Pb(NO3)2(aq) 0 PbCrO4(s) 2KNO3(aq) chromate, determine the mass of lead chromate formed. 1 mol PbCrO __ 4 1 mol CHCl3 4 4 1 mol CH4 68. Oxygen Production The Russian Space Agency uses potassium superoxide (KO2) for the chemical oxygen generators in their space suits. 4KO2 2H2O 4CO2 0 4 KHCO3 3O2 Complete Table 11.3. Mass KO2 Mass H2O Mass CO2 Mass KHCO3 Mass O2 1100 g 140 g 7.0 102 g 1600 g 380 g 380 g O2 (1 mol O2/32.00 g O2) (4 mol KO2/3 mol O2) (71.1 g KO2/1 mol KO2) 1100 g 4 1 mol K2CrO4 323.2 g PbCrO __ 80.8 g PbCrO 4 4 1 mol PbCrO4 3 119.37 g CHCl3 Oxygen Generation Reaction Data b. Starting with 0.250 mol of potassium 0.250 mol K2CrO4 1 mol CHCl 1 mol CH __ __ 16.04 g CH __ 6.72 g CH 8 18 65. A solution of potassium chromate reacts with a 67. Chloroform (CHCl3), an important solvent, is 66. Rocket Fuel The exothermic reaction between liquid hydrazine (N2H2) and liquid hydrogen peroxide (H2O2) is used to fuel rockets. The products of this reaction are nitrogen gas and water. a. Write the balanced chemical equation. N2H2(l) H2O2(l) 0 N2(g) 2H2O(g) 380 g O2 (1 mol O2/32.00 g O2) (2 mol H2O/3 mol O2) (18.02 g H2O/1 mol H2O) 140 g 380 g O2 (1 mol O2/32.00 g O2) (4 mol CO2/3 mol O2) (44.01 g CO2/1 mol CO2) 7.0 102 g 380 g O2 (1 mol O2/32.00 g O2) (4 mol KHCO3/3 mol O2) (100.12 g KHCO3/1 mol KHCO3) 1600 g b. How much hydrazine, in grams, is needed to produce 10.0 mol of nitrogen gas? 10.0 mol N2 1 mol N H 30.03 g N H __ __ 2 2 1 mol N2 3.00 102 g N2H2 222 2 2 1 mol N2H2 Chemistry: Matter and Change • Chapter 11 Solutions Manual Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. CHAPTER CHAPTER 11 SOLUTIONS MANUAL 69. Gasohol is a mixture of ethanol and gasoline. was extracted is 150.0 g, what percentage of the ore is gold? C2H5OH(l) O2(g) 0 CO2(g) H2O(g) 150.0 g ore C2H5OH(l) 3O2(g) 0 2CO2(g) 3H2O(l) 1 mol C H OH 100.0 g C H OH __ 2 5 2 5 46.08 g C2H5OH 2.170 mol C2H5OH 2.170 mol C2H5OH 4.340 mol CO2 4.340 mol CO2 2 mol CO __ 2 1 mol C2H5OH 50.2 g Au __ 100 33.5% gold in ore 72. Film Photographic film contains silver bromide in gelatin. Once exposed, some of the silver bromide decomposes, producing fine grains of silver. The unexposed silver bromide is removed by treating the film with sodium thiosulfate. Soluble sodium silver thiosulfate (Na3Ag(S2O3)2) is produced. AgBr(s) 2Na2S2O3(aq) 0 Na3Ag(S2O3)2(aq) NaBr(aq) 44.01 g CO __ 2 1 mol CO2 191.0 g CO2 produced 70. Car Battery Car batteries use lead, lead(IV) oxide, and a sulfuric acid solution to produce an electric current. The products of the reaction are lead(II) sulfate in solution and water. a. Write the balanced chemical equation for this reaction. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. b. If the mass of the ore from which the gold Balance the equation, and determine the mass of CO2 produced from the combustion of 100.0 g of ethanol. Pb(s) PbO2(s) 2H2SO4(aq) 0 2PbSO4(aq) 2H2O(l) b. Determine the mass of lead(II) sulfate produced when 25.0 g of lead reacts with an excess of lead(IV) oxide and sulfuric acid. 2 mol PbSO 1 mol Pb 25 g Pb __ __ Determine the mass of Na3Ag(S2O3)2 produced if 0.275 g of AgBr is removed. 0.275 g AgBr 1 mol AgBr __ 187.77 g AgBr 1.46 103 mol AgBr 1.46 103 mol AgBr 1.46 103 1 mol Na Ag(S O ) __ 3 2 3 2 1 mol AgBr mol Na3Ag(S2O3)2 1.46 103 mol Na3Ag(S2O3)2 401.12 g Na3Ag(S2O3)2 0.587 g Na3Ag(S2O3)2 1 mol Na3Ag(S2O3)2 ___ Section 11.3 4 207.2 g Pb 1 mol Pb 303.23 g PbSO4 73.2 g PbSO4 1 mol PbSO4 __ 71. To extract gold from its ore, the ore is treated with sodium cyanide solution in the presence of oxygen and water. 4Au(s) 8NaCN(aq) O2(g) 2H2O(l) 0 4NaAu(CN)2(aq) 4NaOH(aq) a. Determine the mass of gold that can be extracted if 25.0 g of sodium cyanide is used. 25.0 g NaCN 1 mol NaCN 4 mol Au __ __ 49.01 g NaCN 196.97 g Au 50.2 g Au 1 mol Au __ Solutions Manual 8 mol NaCN Mastering Concepts 73. How is a mole ratio used to find the limiting reactant? The actual mole ratio of reactants from the chemical equation is compared to the mole ratio determined from the given quantities. 74. Explain why the statement “the limiting reactant is the reactant with the lowest mass” is incorrect. The limiting reactant is the reactant that produces the lowest number of moles of product. Mass does not determine the limiting reactant, but the number of moles. Chemistry: Matter and Change • Chapter 11 223 11 CHAPTER SOLUTIONS MANUAL 77. Nickel-Iron Battery In 1901, Thomas Edison invented the nickel-iron battery. The following reaction takes place in the battery. M and circles to represent Element N. a. Write the balanced equation for the reaction. 3M2 N2 0 2M3N b. If each square represents 1 mol of M and each circle represents 1 mol of N, how many moles of M and N were present at the start of the reaction? 6 moles of element M (in the form of 3 moles of M2) and 6 moles of element N (likewise, 3 moles of N2) c. How many moles of product form? How many moles of M and N are unreacted? 2 moles of M3N form with 2 moles of N2 unreacted (4 total moles of element N) How many mol of Fe(OH)2 are produced when 5.00 mol of Fe and 8.00 mol of NiO(OH) react? According to the balanced equation, two moles of NiO(OH) react with each mole of Fe. So, 4 mol Fe react with 8.00 mol NiO(OH), leaving 1.00 mol Fe in excess. For each mole of Fe that reacts, one mole of Fe(OH)2(s) is produced. Because 4.0 mol Fe reacts, 4.0 mol Fe(OH)2 is produced. 78. One of the few xenon compounds that form is cesium xenon heptafluoride (CsXeF7). How many moles of CsXeF7 can be produced from the reaction of 12.5 mol of cesium fluoride with 10.0 mol of xenon hexafluoride? CsF(s) XeF6(s) 0 CsXeF7(s). 10.0 mol XeF6 d. Identify the limiting reactant and excess reactant. 7 1 mol XeF6 7 79. Iron Production Iron is obtained commer- M2 is the limiting reactant and N2 is the excess reactant. Mastering Problems 76. The reaction between ethyne (C2H2) and hydrogen (H2) is illustrated in Figure 11.13. The product is ethane (C2H6). Which is the limiting reactant? Which is the excess reactant? Explain. → + 1 mol CsXeF __ 10.0 mol CsXeF + cially by the reaction of hematite (Fe2O3) with carbon monoxide. How many grams of iron are produced if 25.0 mol of hematite react with 30.0 mol of carbon monoxide? Fe2O3(s) 3CO(g) 0 2Fe(s) 3CO2(g) According to the balanced equation, 1 mole of hematite reacts with 3 moles of carbon monoxide. Since 25.0 mol of hematite would require 75.0 mol CO but only 30.0 mol are available, CO is the limiting reactant. 30.0 mol CO 55.85 g Fe 2 mol Fe _ _ 3 mol CO 1 mol Fe 1120 g Fe Ethyne Hydrogen Ethane Ethyne Hydrogen is limiting; ethyne is the excess reactant. One mol of ethyne is left over. 224 Chemistry: Matter and Change • Chapter 11 Solutions Manual Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 75. Figure 11.12 uses squares to represent Element Fe(s) 2NiO(OH)(s) 2H2O(l) 0 Fe(OH)2(s) 2Ni(OH)2(aq) 11 CHAPTER SOLUTIONS MANUAL 80. The reaction of chlorine gas with solid 82. Lithium reacts spontaneously with bromine to phosphorus (P4) produces solid phosphorus pentachloride. When 16.0 g of chlorine reacts with 23.0 g of P4, which reactant is limiting? Which reactant is in excess? produce lithium bromide. Write the balanced chemical equation for the reaction. If 25.0 g of lithium and 25.0 g of bromine are present at the beginning of the reaction, determine 10Cl2(g) P4(s) 0 4PCl5(s) 2Li(s) Br2(l) 0 2LiBr(s) 1 mol CI __ 0.226 mol CI 23.0 g P4 a. the limiting reactant. 2 16.0 g Cl2 2 70.90 g CI2 25.0 g Li 1 mol P __ 0.185 moles 1 mol Li _ 3.60 mol Li 6.94 g Li 4 123.88 g P4 According to the balanced equation, Cl2 reacts with P4 in a ten-to-one ratio. 0.226 mol Cl2 1 mol P _ 4 10 mol CI2 0.0226 mol P4 needed 25.0 g Br2 1 mol Br __ 0.156 mol Br 2 159.80 g Br2 Actual ratio of mol Li to mol Br2 is 3.60 mol Li/0.156 Br2 or 23:1. Only 2 mol Li are required for 1 mol Br2. Thus, Br2 is the limiting reactant. b. the mass of lithium bromide produced. Cl2 is limiting reactant; P4 is in excess. 0.156 mol Br2 2 mol LiBr _ 0.312 mol LiBr 0.312 mol LiBr 86.84 g LiBr __ 27.1 g LiBr 81. Alkaline Battery An alkaline battery Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. produces electrical energy according to this equation. Zn(s) 2MnO2(s) H2O(l) 0 Zn(OH)2(s) Mn2O3(s) a. Determine the limiting reactant if 25.0 g of Zn and 30.0 g of MnO2 are used. 25.0 g Zn 1 mol Zn _ 0.380 mol Zn 65.3 g Zn 30.0 g MnO2 1 mol MnO __ 2 According to the balanced equation, MnO2 reacts with Zn in a two-to-one ratio. In the reaction, the ratio is 1:1.1 or 0.345/0.380. MnO2 is the limiting reactant. b. Determine the mass of Zn(OH)2 produced. 1 mol Zn(OH) __ 2 2 mol MnO2 99.39 g Zn(OH) __ 17.1 g Zn(OH) 2 1 mol Zn(OH)2 2 1 mol Br2 1 mol LiBr c. the excess reactant and the excess mass. Li is in excess. 0.156 mol Br2 2 mol Li _ 0.312 mol Li used 1 mol Br2 3.60 mol Li 0.312 mol Li used 3.29 mol Li remaining 3.29 mol Li 86.92 g MnO2 0.345 mol MnO2 0.345 mol MnO2 2 6.94 g Li _ 22.8 g Li remaining 1 mol Li Section 11.4 Mastering Concepts 83. What is the difference between actual yield and theoretical yield? Actual yield is the amount of product actually obtained experimentally. Theoretical yield is the amount of product predicted by a stoichiometric calculation. 84. How are actual yield and theoretical yield determined? Actual yield is determined through experimentation. Theoretical yield is calculated from a given reactant or the limiting reactant. Solutions Manual Chemistry: Matter and Change • Chapter 11 225 11 SOLUTIONS MANUAL 85. Can the percent yield of a chemical reaction be more than 100%? Explain your answer. No, you cannot produce more product than the theoretical yield, which is determined from the starting reactants. 86. What relationship is used to determine the percent yield of a chemical reaction? Mastering Problems 90. Ethanol (C2H5OH) is produced from the fermentation of sucrose (C12H22O11) in the presence of enzymes. C12H22O11(aq) H2O(g) 0 4C2H5OH(l) 4CO2(g) Determine the theoretical yield and the percent yield of ethanol if 684 g of sucrose undergoes fermentation and 349 g of ethanol is obtained. actual yeild __ 100 percent yield theoretical yield 87. What experimental information do you need in order to calculate both the theoretical and the percent yield of any chemical reaction? The quantity of one reactant and the actual yield of the product 88. A metal oxide reacts with water to produce a metal hydroxide. What additional information would you need to determine the percent yield of metal hydroxide from this reaction? the mass of one substance in the reaction and the actual mass of metal hydroxide produced 89. Examine the reaction represented in Figure 11.14. Determine if the reaction went to completion. Explain your answer, and calculate the percent yield of the reaction. Element A Element B theoretical yield: 684 g C12H22O11 1 mol C H O __ 12 22 11 342.23 g C12H22O11 46.07 g C H OH 4 mol C H OH __ __ 2 5 2 5 1 mol C12H22O11 369 g C2H5OH % yield 1 mol C2H5OH actual yield __ 100 theoretical yield 349 g 100 94.6% 369 g _ 91. Lead(II) oxide is obtained by roasting galena, lead(II) sulfide, in air. The unbalanced equation is: PbS(s) O2(g) 0 PbO(s) SO2(g) a. Balance the equation, and determine the theoretical yield of PbO if 200.0 g of PbS is heated. 2PbS 3O2 0 2PbO 2SO2 Theoretical yield 200.0 g PbS The reaction did not go to completion. Using squares to represent Element A and circles to represent Element B, the initial products would have yielded four AB2 particles, but only three were produced. There are enough remaining unreacted A and B particles to produce one more AB2 particle. The percent yield is 75%. 226 Chemistry: Matter and Change • Chapter 11 1 mol PbS __ 239.27 g PbS 223.19 g PbO 2 mol PbO __ __ 186.6 g PbO 2 mol PbS 1 mol PbO b. What is the percent yield if 170.0 g of PbO is obtained? % yield 170.0 g _ 100 91.10% 186.6 g Solutions Manual Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. CHAPTER CHAPTER 11 SOLUTIONS MANUAL 92. Upon heating, calcium carbonate (CaCO3) c. What is the theoretical yield of H2SiF6? decomposes to produce calcium oxide (CaO) and carbon dioxide (CO2). a. Determine the theoretical yield of CO2 if 235.0 g of CaCO3 is heated. 2.00 mol HF 0.333 mol H2SiF6 1 mol CaCO __ 100.06 g CaCO 43.99 g CO 1 mol CO __ __ 103 g CO 1 mol CO2 2 b. What is the percent yield of CO2 if 97.5 g of actual yield __ 100 theoretical yield 97.5 g CO __ 100 94.7% % yield 45.8 g H SiF __ 100 95.4% yield 2 6 48.0 H2SiF6 94. Van Arkel Process Pure zirconium is % yield 2 103 g CO2 93. Hydrofluoric acid solutions cannot be stored in glass containers because HF reacts readily with silica dioxide in glass to produce hexafluorosilicic acid (H2SiF6). SiO2(s) 6HF(aq) 0 H2SiF6(aq) 2H2O(l) Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 6 d. What is the percent yield? CO2 is collected? 40.0 g SiO2 and 40.0 g HF react to yield 45.8 g H2SiF6. a. What is the limiting reactant? 40.0 g SiO2 2 1 mol H2SiF6 48.0 g H2SiF6 is the theoretical yield. 3 2 2 6 144.11 g H SiF __ 48.0 g H2SiF6 3 1 mol CaCO3 2 6 mol HF 0.333 mol H2SiF6 CaCO3(s) 0 CaO(s) CO2(g) 235 g CaCO3 1 mol H SiF __ __ 0.666 mol SiO 1 mol SiO2 2 60.09 g SiO2 obtained using the two-step Van Arkel process. In the first step, impure zirconium and iodine are heated to produce zirconium iodide (ZrI4). In the second step, ZrI4 is decomposed to produce pure zirconium. ZrI4(s) 0 Zr(s) 2I2(g) Determine the percent yield of zirconium if 45.0 g of ZrI4 is decomposed and 5.00 g of pure Zr is obtained. theoretical yield 45.0 g ZrI4 1 mol ZrI __ 4 598.84 g ZrI4 91.22 g Zr 1 mol Zr _ _ 6.85 g of Zr 1 mol ZrI4 1 mol Zr actual yield __ 100 theoretical yield 5.00 g Zr _ 100 73.0% % yield 1 mol HF 40.0 g HF __ 2.00 mol HF 20.01 g HF Ratio of HF to SiO2 in the balanced equation is 6:1. Actual ratio of HF to SiO2 is 2.00 mol HF or 3.00:1. Thus, HF is the 0.666 mol SiO2 limiting reactant. 6.85 g Zr __ b. What is the mass of the excess reactant? 2.00 mol HF 1 mol SiO __ 0.333 mol SiO 2 2 6 mol HF 0.666 mol SiO2 available 0.333 mol SiO2 used 0.333 mol SiO2 in excess 0.333 mol SiO2 60.09 g SiO __ 2 1 mol SiO2 20.0 g SiO2 in excess Solutions Manual Chemistry: Matter and Change • Chapter 11 227 11 SOLUTIONS MANUAL According to the balanced equation, Ca3(PO4)2 reacts with SiO2 in a one-to-three ratio. In this reaction, SiO2 is in excess and 0.8060 mol of Ca3(PO4)2 react. 95. Methanol, wood alcohol, is produced when carbon monoxide reacts with hydrogen gas. CO 2H2 0 CH3OH When 8.50 g of carbon monoxide reacts with an excess of hydrogen, 8.52 g of methanol is collected. Complete Table 11.4, and calculate the percent yield for this reaction. CO(g) CH3OH(l) Mass 8.50 g 9.71 g Molar mass 28.01 g/mol 32.05 g/mol Moles 0.303 mol 0.303 mol 0.303 mol CO (1 mol CH3OH/1 mol CO) 0.303 mol CH3OH Percent yield (8.52 g/9.71 g) 100 87.7% yield 96. Phosphorus (P4) is commercially prepared by heating a mixture of calcium phosphate (CaSiO3), sand (SiO2), and coke (C) in an electric furnace. The process involves two reactions. 10 49.92 g of P4 1 mol P 123.88 g P __ __ 4 4 1 mol P4O10 1 mol P4 Step 4 is to determine the percent yield, given actual yield is 49.92 g. actual yield __ 100 theoretical yield 45.0 g P _ 100 90.1% 4 49.92 g P4 97. Chlorine forms from the reaction of hydro- chloric acid with manganese(IV) oxide. The balanced equation is: Calculate the theoretical yield and the percent yield of chlorine if 86.0 g of MnO2 and 50.0 g of HCl react. The actual yield of Cl2 is 20.0 g. Step 1: The balanced equation is given. P4O10(g) 10C(s) 0 P4(g) 10CO(g) The P4O10 produced in the first reaction reacts with an excess of coke (C) in the second reaction. Determine the theoretical yield of P4 if 250.0 g of Ca3(PO4)2 and 400.0 g of SiO2 are heated. If the actual yield of P4 is 45.0 g, determine the percent yield of P4. Step 1 is to determine the excess quantity in equation #1. 228 4 2 mol Ca3(PO4)2 MnO2 4HCl 0 MnCl2 Cl2 2H2O 2Ca3(PO4)2(s) 6SiO2(s) 0 6CaSiO3(l) P4O10(g) 0.8060 mol 1 mol P O __ % yield 0.304 mol CH3OH (32.05 g CH3OH/1 mol CH3OH) 9.71 g CH3OH 1 mol SiO __ 6.657 mol of SiO 2 2 60.08 g SiO2 1 mol Ca (PO ) __ 3 0.4030 mol P4O10 0.4030 mol P4O10 8.50 g CO (1 mol CO/28.01 g CO) 0.303 mol CO 250.0 g Ca3(PO4)2 0.8060 mol Ca3(PO4)2 Step 3 is to determine amount of P4 produced in step 2 from 0.4030 mol P4O10. Methanol Reaction Data 400.0 g SiO2 Step 2 is to determine amount of P4O10 produced. MnO2 (s) 4HCl (aq) 0 MnCl2 (aq) Cl2 (g) 2H2O (l) Step 2 is to determine which reactant is in excess. 86.0 g MnO2 50.0 g HCl 1 mol MnO __ 0.989 mol MnO 2 2 86.94 g MnO2 1 mol HCI __ 1.37 mol HCI 36.46 g HCI According to the balanced equation, MnO2 reacts with HCl in a one-to-four ratio. In this reaction, the ratio is 0.989 mol/1.37 mol or 1:1.38. Therefore MnO2 is in excess, and HCl is the limiting reactant. 4 2 310.17 g Ca3(PO4)2 Chemistry: Matter and Change • Chapter 11 Solutions Manual Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. CHAPTER CHAPTER 11 SOLUTIONS MANUAL Step 3 is to determine the grams of Cl2 produced. 1.37 mol HCl a. Write the balanced chemical equation for the formation of nitrogen dioxide from nitrogen oxide. 1 mol CI 70.90 g CI _ __ 2 4 mol HCI 24.3 g CI2. 2 1 mol CI2 2NO(g) O2(g) 0 2NO2(g) Step 4 is to determine percent yield, given that 20.0 g of Cl2 is actually formed. b. What mole ratio would you use to convert from moles of nitrogen oxide to moles of nitrogen dioxide? _ 100 82.3% 20.0 g CI2 24.3 g CI2 2 mol NO __ 2 2 mol NO Mixed Review 98. Ammonium sulfide reacts with copper(II) nitrate in a double replacement reaction. What mole ratio would you use to determine the moles of NH4NO3 produced if the moles of CuS are known? 102. Electrolysis Determine the theoretical and percent yield of hydrogen gas if 36.0 g of water undergoes electrolysis to produce hydrogen and oxygen and 3.80 g of hydrogen is collected. (NH4)2S Cu(NO3)2 0 2NH4NO3 CuS 2H2O(l) 0 H2(g) O2(g) 2 mol NH NO __ 36.0 g H2O (1 mol H2O/18.02 g H2O) 2.00 mol 4 3 1 mol CuS theoretical yield 2.00 mol H2O (CaNCN) can be used as a nitrogen source for crops. To obtain this compound, calcium carbide is reacted with nitrogen at high temperatures. CaC2(s) N2(g) 0 CaNCN(s) C(s) What mass of CaNCN can be produced if 7.50 mol of CaC2 reacts with 5.00 mol of N2? 5.00 mol N2 80.11 g CaNCN 1 mol CaNCN __ __ 1 mol N2 1 mol CaNCN 401 g CaNCN 100. When copper(II) oxide is heated in the presence of hydrogen gas, elemental copper and water are produced. What mass of copper can be obtained if 32.0 g of copper(II) oxide is used? CuO H2 0 Cu H2O 32.0 g CuO 1 mol Cu 1 mol CuO __ __ 79.55 g CuO 1 mol CuO 63.55 g Cu __ 25.6 g Cu 1 mol Cu 101. Nitrogen oxide is present in urban pollution, but it immediately converts to nitrogen dioxide as it reacts with oxygen. Solutions Manual 2.02 g H _ 4.04 g H 2 2 mol H2O 2 2 1 mol H2 % yield 3.80 g H _ 100 94.1% 2 4.04 g H2 103. Iron reacts with oxygen as shown. Mass of Fe2O3 Formed From Burning Fe Mass of Fe2O3 (g) Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 99. Fertilizer The compound calcium cyanamide 1 mol H __ 30 20 10 0 0 5 10 15 20 25 30 35 Mass of Fe (g) 4Fe(s) 1 3O2(g) 0 2Fe2O3(s) Different amounts of iron were burned in a fixed amount of oxygen. For each mass of iron burned, the mass of iron(II) oxide formed was plotted on the graph shown in Figure 11.15. Why does the graph level off after 25.0 g of iron is burned? How many moles of oxygen are present in the fixed amount? Chemistry: Matter and Change • Chapter 11 229 11 SOLUTIONS MANUAL sulfate. Determine the actual yield of copper(II) sulfate. Divide the actual yield by the theoretical yield and multiply by 100 to determine percent yield of copper(II) sulfate. The graph levels off because the oxygen limits the reaction at that point. 35.0 g Fe2O3 0.329 mol O2 1 mol Fe O 3 mole O __ __ 2 3 159.7 g Fe2O3 2 2 mole Fe2O3 107. Apply Concepts When a campfire begins to die down and smolder, the flame can be rekindled if you start to fan it. Explain in terms of stoichiometry why the fire begins to flare up again. Think Critically 104. Analyze and Conclude In an experiment, you obtain a percent yield of product of 108%. Is such a percent yield possible? Explain. Assuming that your calculation is correct, what reasons might explain such a result? When you fan the flame, additional oxygen is added and the remaining coals can burn. 108. Apply Concepts Students conducted a lab to investigate limiting and excess reactants. The students added different volumes of sodium phosphate solution (Na3PO4) to a beaker. They then added a constant volume of cobalt(II) nitrate solution (Co(NO3)2), stirred the contents, and allowed the beakers to sit overnight. The next day, each beaker had a purple precipitate formed at the bottom. The students decanted the supernatant from each beaker, divided it into two samples, and added one drop of sodium phosphate solution to one sample and one drop of cobalt(II) nitrate solution to the second sample. Their results are shown in Table 11.5. No, percent yields cannot be greater than 100%. High results could mean the product was not completely dry, or it was contaminated. 105. Observe and Infer Determine whether each reaction depends on a limiting reactant. Explain why or why not, and identify the limiting reactant. a. Potassium chlorate decomposes to form potassium chloride and oxygen. No, because there is only one reactant. b. Silver nitrate and hydrochloric acid react to produce silver chloride and nitric acid. Yes, because there are two reactants. Not enough information is given to identify which is the limiting reactant. Reaction with Drop of Na3PO4 Reaction with Drop of Co(NO3)2 Trial Volume Na3PO4 Volume Co(NO3)2 ment that can be used to determine the percent yield of anhydrous copper(II) sulfate when copper(II) sulfate pentahydrate is heated to remove water. 1 5.0 mL 10.0 mL purple no precipitate reaction 2 10.0 mL 10.0 mL no reaction purple precipitate Obtain and record the mass of an empty evaporating dish. Add 2.00 g of copper(II) sulfate pentahydrate and obtain and record the mass of the hydrate and evaporating dish. Heat the dish gently for 5 minutes, then strongly for 5 minutes to drive off the water. Cool the dish and remass. Record. Determine the mass of the anhydrous copper sulfate. Using the equation CuSO4·5H2O 0 CuSO4 5H2O and the initial mass of the copper(II) sulfate pentahydrate, determine the theoretical yield of copper(II) 3 15.0 mL 10.0 mL no reaction purple precipitate 4 20.0 mL 10.0 mL no reaction purple precipitate 106. Design an Experiment Design an experi- 230 Reaction Data for Co(NO3)2 and Na3PO4 Chemistry: Matter and Change • Chapter 11 a. Write a balanced chemical equation for the reaction. 2Na3PO4 (aq) 3Co(NO3)2 (aq) 0 Co3(PO4)2 (s) 6NaNO3 (aq) Solutions Manual Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. CHAPTER CHAPTER 11 b. Based on the results, identify the limiting b. Write balanced equations for the steps of reactant and the excess reactant for each trial. the reaction. Trial 1: Na3PO4 is limiting, Co(NO3)2 is in excess because the addition of Na3PO4 caused an additional reaction. VO2 2H2 0 V 2H2O Trials 2-4: Co(NO3)2 is limiting, Na3PO4 is in excess because the addition of Co(NO3)2 caused and additional reaction. Challenge Problem 109. When 9.59 g of a certain vanadium oxide is heated in the presence of hydrogen, water and a new oxide of vanadium are formed. This new vanadium oxide has a mass of 8.76 g. When the second vanadium oxide undergoes additional heating in the presence of hydrogen, 5.38 g of vanadium metal forms. a. Determine the empirical formulas for the two vanadium oxides. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. SOLUTIONS MANUAL V: 5.38 g __ 0.106 mol O: 4.21 g __ 0.263 mol 50.94 g/mol 15.999 g/mol Divided the smallest molar quantity. 0.106 mol _ 1 0.106 mol 0.263 mol _ 2.48 艐 2.5 0.106 mol Multiply by the mole ratio by 2. 2 (1 mol V: 2.5 mol O) V2O5 V: O: 5.38 g __ 0.106 mol 50.94 g/mol 3.38 g __ 0.211 mol 15.999 g/mol Divided the smallest molar quantity. 0.106 mol _ 1 0.106 mol 0.211 mol _ 1.99 艐 2 V2O5 H2 0 2VO2 H2O c. Determine the mass of hydrogen needed to complete the steps of this reaction. 9.59 g V2O5 1 mol H2 __ __ 181.88 g/mol 1 mol V2O5 2.016 g H2 __ 0.106 g H2 1 mol H2 2 mol H2 8.76 g VO2 __ _ 82.94 g/mol 1 mol VO2 2.016 g H2 0.426 g H2 1 mol H2 __ Total hydrogen mass 0.106 g 0.426 g 0.532 g H2 Cumulative Review 110. You observe that sugar dissolves more quickly in hot tea than in iced tea.You state that higher temperatures increase the rate at which sugar dissolves in water. Is this statement a hypothesis or a theory? Why? (Chapter 1) a hypothesis, because it is based only on observation, not on data 111. Write the electron configuration for each of the following atoms. (Chapter 5) a. fluorine [He]2s22p5 b. aluminum [Ne]3s23p1 c. titanium [Ar]4s23d2 d. radon [Xe]6s24f145d106p6 0.106 mol 1 mol V: 2 mol O VO2 Solutions Manual Chemistry: Matter and Change • Chapter 11 231 11 CHAPTER SOLUTIONS MANUAL 112. Explain why the gaseous nonmetals exist b. What is the empirical formula of butanoic as diatomic molecules, but other gaseous elements exist as single atoms. (Chapter 8) acid? Diatomic molecules achieve a noble gas electron configuration by forming covalent bonds. The monoatomic gases already have noble gas electron configurations. 9.1 g H (1 mol/1.01 g) 9.0 mol 113. Write a balanced equation for the reaction of potassium with oxygen. (Chapter 9) 54.5 g C (1 mol/12.01 g) 4.54 mol 36.4 g O (1 mol/16.00 g ) 2.28 mol 4.54 mol C/2.28 mol O 2 9.0 mol H/2.28 mol O 4 2.28 mol O/2.28 mol O 1 4K(s) O2(g) 0 2K2O(s) The empirical formula is C2H4O. 114. What is the molecular mass of UF6? What is the molar mass of UF6? (Chapter 10) Additional Assessment 352.02 amu, 352.02 g/mol 116. Air Pollution Research the air pollutants 115. Figure 11.16 gives percent composition data for several organic compounds. (Chapter 10) Percent Composition of Some Organic Compounds %C %H %O 40.0 Percent by mass 52.2 50 40 53.3 54.5 54.5 36.4 34.8 36.4 30 13.0 10 6.7 Ethanol 9.1 9.1 Formaldehyde Acetaldehyde Butanoic acid Compound name a. How are the molecular and empirical formulas of acetaldehyde and butanoic acid related? They are whole number multiples of one another. 232 Answers will vary. Common pollutants are SO2, NO, NO2 and O3. Check that stoichiometric calculations account for a decrease in the pollutant. 117. Haber Process The percent yield of 20 0 produced by combustion of gasoline in internal combustion engines. Discuss the common pollutants and the reaction that produces them. Show, through the use of stoichiometry, how each pollutant could be reduced if more people used mass transit. Chemistry: Matter and Change • Chapter 11 ammonia produced when hydrogen and nitrogen are combined under ordinary conditions is extremely small. However, the Haber Process combines the two gases under a set of conditions designed to maximize yield. Research the conditions used in the Haber Process, and find out why the development of the process was of great importance. Answers will vary. Make sure the equation, N2(g) 3H2(g) 2NH3(g) 92 kJ, is included. The aim of the Haber process was to control a reaction so that a large amount of a useful product was yielded quickly. The process was of great importance because the Germans had to come up with a nitrogen compound that could be produced in large amounts. Solutions Manual Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 238.03 6(18.998) 352.02 CHAPTER 11 SOLUTIONS MANUAL 2 mol C6H4(OH)2 __ from eqauation Document-Based Questions 4 mol H2O2 Bombardier Beetles Many insects secrete hydrogen peroxide (H2O2) and hydroquinone C6H4(OH)2. Bombardier beetles take this a step further by mixing these chemicals with a catalyst. The result is an exothermic chemical reaction and a spray of hot, irritating chemicals for any would-be predator. Researchers hope to use a similar method to reignite aircraft turbine engines. H2O2 is the limiting reactant. 119. What is the excess reactant, and how many milligrams are in excess? 2 mol C H (OH) __ 4 mol H O 110.12 g C H (OH) 1 mg __ __ 2 6 4 100.0 mg 80.9 mg 19.1 mg of C6H4(OH)2 in excess 120. How many milligrams of benzoquinone will be produced? 1.47 103 mol H2O2 H2O2 H2O O2 Energy 108.09 g C6H4O2 __ O C6H4(OH)2 Hydroquinone C6H4O2 Benzoquinone Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 118. If the bombardier beetle stores 100.0 mg of hydroquinone (C6H4(OH)2) along with 50.0 mg of hydrogen peroxide (H2O2), what is the limiting reactant? Balanced reaction: 2C6H4(OH)2 4H2O2 0 2C6H4O2 6H2O O2 100 mg 50 mg 2 mol C6H4O2 __ 4 mol H2O2 1 mg __ 1 mol C6H4O2 1 103 g 79.4 mg C6H4O2 produced Catalyst OH 2 2 O OH 2 1 mol C6H4(OH)2 1 103 g 80.9 mg C6H4(OH)2 used Figure 11.17 below shows the chemical reaction that results in the bombardier beetle’s defensive spray. Data obtained from: Becker, Bob. April 2006. ChemMatters. 24: no.2 6 4 1.47 103 mol H2O2 Standardized Test Practice pages 398–399 1. Stoichiometry is based on the law of a. b. c. d. constant mole ratios. Avogadro’s constant. conservation of energy. conservation of mass. d ? mg C6H4(OH)2 H2O2 0 C6H4O2 H2O O2 energy Use the graph below to answer Questions 2–5. Supply of Various Chemicals in Dr. Raitano’s Laboratory __ 3 100.0 mg C6H4(OH)2 1 10 g 1 mg 1 mol __ 9.08 104 mol 110.00 g C6H4(OH)2 C6H4(OH)2 NaCl 700.0 g Na2CO3 500.0 g Ca(OH)2 300.0 g __ __ 3 1 mol 50.0 mg H2O2 1 10 g 1 mg 34.02 g H2O2 1.47 103 mol H2O2 ___ 9.08 104 mol C6H4(OH)2 AgNO3 100.0 g KClO3 200.0 g NaH2PO4 350.0 g 1.47 103 mol H2O2 0.618 mol C6H4(OH)2 __ from reaction vs. 1 mol H2O2 Solutions Manual Chemistry: Matter and Change • Chapter 11 233 11 SOLUTIONS MANUAL 2. Pure silver metal can be made using the reac- Cu(s) 2AgNO3(aq) 0 2Ag(s) Cu(NO3)2(aq) 2KClO3(s) 0 2KCl(s) 3O2(g) How many grams of copper metal will be needed to use up all of the AgNO3 in Dr. Raitano’s laboratory? a. 18.70 g b. 37.3 g c. 74.7 g d. 100 g a 100.0 g AgNO3 __ 1 mol AgNO 1mol Cu __ __ 3 169.88 g AgNO3 63.55w g Cu 18.70 g Cu 1 mol Cu 2 mol AgNO3 of manufacturing sodium hydroxide. The equation for this process is as follows. Na2CO3(aq) Ca(OH)2(aq) 0 2NaOH(aq) CaCO3(s) Using the amounts of chemicals available in Dr. Raitano’s lab, what is the maximum number of moles of NaOH that can be produced? a. 4.05 mol b. 4.72 mol c. 8.097 mol d. 9.43 mol c Find the limiting reactant. 1 mol Na CO __ 2 __ 1 mol Ca2 (OH)2 74.10 g Ca(OH)2 4.049 mol Ca(OH)2 Ca(OH)2 is the limiting reactant. 4.049 mol Ca(OH)2 b _1 (200.0 g KCIO3) 100.0 g KCIO3 2 theoretical yield 100.0 g KCIO3 1 mol KCIO __ 3 122.5 g KCIO3 32.00 g O 3 mol O __ __ 39.17 g O 2 2 2 mol KCIO3 percent 2 1 mol O2 actual yield 12.8 g __ 100 _ 39.17 g theoretical yield 100 32.7% 5. Sodium dihydrogen pyrophosphate (Na2H2P2O7), more commonly known as baking powder, is manufactured by heating NaH2PO4 at high temperatures: 2NaH2PO4(s) 0 Na2H2P2O7(s) H2O(g) If 444.0 g of Na2H2P2O7 is needed, how much more NaH2PO4 will Dr. Raitano have to buy to make enough Na2H2P2O7? a. 0.00 g b. 94.0 g c. 130.0 g d. 480 g 3 106.00 g Na2CO3 4.717 mol Na2CO3 300.0 g Ca(OH)2 If half of the KClO3 in the lab is used and 12.8 g of oxygen gas is produced, what is the percent yield of this reaction? a. 12.8% b. 32.7% c. 65.6% d. 98.0% 3. The LeBlanc process is the traditional method 500.0 g Na2CO3 4. Pure O2 gas can be generated from the decom- position of potassium chlorate (KClO3): tion shown below. 2 mol NaOH __ c 1 mol Na H P O __ 221.94 g Na H P O 119.98 g NaH PO 2 mol NaH PO __ __ 2 2 2 444.0 g Na2H2P2O7 2 4 1 mol Na2H2P2O7 48.0 g NaH2PO4 7 2 2 2 2 7 4 1 mol Na2H2PO4 480.0 g 350.0 g 130.0 g 1 mol Ca(OH)2 8.097 mol NaOH 234 Chemistry: Matter and Change • Chapter 11 Solutions Manual Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. CHAPTER CHAPTER 11 SOLUTIONS MANUAL 6. Red mercury(II) oxide decomposes at high temperatures to form mercury metal and oxygen gas: 2HgO(s) 0 2Hg(l) O2(g) If 3.55 mol of HgO decomposes to form 1.54 mol of O2 and 618 g of Hg, what is the percent yield of this reaction? a. 13.2% b. 42.5% c. 56.6% d. 86.8% d __ 1 mol O2 theoretical yield O2 3.55 mol HgO 2 mol HgO 1.775 mol O2 percent yield 1.54 mol _ 100 86.8% Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. (CH3)2N2H2(l) 2N2O4(l) 0 3N2(g) 4H2O(g) 2CO2(g) Because this reaction produces an enormous amount of energy from a small amount of reactants, it was used to drive the rockets on the Lunar Excursion Modules (LEMs) of the Apollo space program. If 18.0 mol of dinitrogen tetroxide is consumed in this reaction, how many moles of nitrogen gas will be released? Set up a mole ratio: 27 moles N2 18 1 13 14 15 16 17 2 neously upon contact with dinitrogen tetroxide (N2O4): 18 moles N2O4 1.775 mol PERIODIC TABLE Y Y Y Y Y Y 9. Dimethyl hydrazine (CH3)2N2H2 ignites sponta- W W Y Y 3 4 5 6 7 8 9 10 11 12 W W Y Z Z Z Z Z Z Z Z Z Z W W Y Z Z Z Z Z Z Z Z Z Z W W Y Z Z Z Z Z Z Z Z Z Z W W W W W W W W W W W W W W W W W Y W W W W W Y Y Z Z Z X X X X X X X X X X X X X X X X X X X X X X X X X X X X 7. Which elements tend to have the largest atomic radius in their periods? a. W b. X c. Y d. Z 3 mole N __ 2 2 moles N2O4 3 moles N __ 2 2 moles N2O4 Use the table below to answer questions 10 and 11. First Ionization Energy of Period 3 Elements Element Atomic Number 1st Ionization Energy, kJ/mol Sodium 11 496 Magnesium 12 736 Aluminum 13 578 Silicon 14 787 Phosphorus 15 1012 Selenium 16 1000 Chlorine 17 1251 Argon 18 1521 c 8. Elements labeled W have their valence electrons in which sublevel? a. s b. p c. d d. f b Solutions Manual Chemistry: Matter and Change • Chapter 11 235 11 CHAPTER SOLUTIONS MANUAL 10. Plot the data from this data table. Place atomic numbers on the x-axis. Use the pictures below to answer Questions 13–17. a. Data should form an approximately linear relationship with a few jagged edges, similar to Figure 6.16 on page 191. First Ionization Energy (Kj/mol) Atomic Number vs. First Ionization Energy b. 1600 1400 1200 1000 800 600 400 200 c. 10 12 14 16 18 Atomic Number energy. How does ionization energy relate to the number of valence electrons in an element? d. Ionization generally increases as you move across a period or row in the periodic table. Elements in the first few families have only 1 or 2 valence electrons, which are relatively easy to remove since this will result in a complete outer shell. Elements on the right side of the periodic table have very high ionization energies because their outer shells are nearly filled, therefore making it more likely for these elements to gain a few electrons rather than lose many. e. 12. How much cobalt(III) titanate (Co2TiO4), in moles, is in 7.13 g of the compound? a. 2.39 101 mol b. 3.10 102 mol c. 3.22 101 mol d. 4.17 102 mol 13. Hydrogen sulfide displays this molecular shape. a 14. Molecules with this shape have four shared pairs of electrons and no lone pairs of electrons. c 15. This shape of molecule is referred to as trigonal planar. b b 7.13 g Co2TiO4 3.10 102 mol 1 mol Co TiO __ 0.0310 mol 2 4 229.74 g Co2TiO4 16. Carbon dioxide displays this molecular shape. d 17. Molecules with this shape undergo sp2 hybridization. b 236 Chemistry: Matter and Change • Chapter 11 Solutions Manual Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 11. Summarize the general trend in ionization
