Chapter 8 Quantities in Chemical Reactions

Day 1 Dec. 12 th Section:

Warm-up Write the balanced equation for when Sodium hydroxide reacts with copper(II) sulfate. Write the balanced equation for when Sodium hydroxide reacts with copper(II) sulfate. Write the balanced equation for when calcium nitrate and magnesium chloride react. Write the balanced equation for when calcium nitrate and magnesium chloride react.

8.1- Global warming: Too much Carbon Dioxide The amount of every substance used and made in a chemical reaction is related to the amounts of all the other substances in the reaction. The amount of every substance used and made in a chemical reaction is related to the amounts of all the other substances in the reaction. Law of Conservation of Mass. Law of Conservation of Mass. Balancing equations by balancing atoms. Balancing equations by balancing atoms. The study of the numerical relationship between chemical quantities in a chemical reaction is called stoichiometry. The study of the numerical relationship between chemical quantities in a chemical reaction is called stoichiometry.

8.2- Making Pancakes The number of pancakes you can make depends on the amount of the ingredients you use. The number of pancakes you can make depends on the amount of the ingredients you use. This relationship can be expressed mathematically. 1 cup flour  2 eggs  ½ tsp baking powder  5 pancakes 1 cup flour + 2 eggs + ½ tsp baking powder  5 pancakes

Making Pancakes, Continued If you want to make more or less than 5 pancakes, you can use the number of eggs you have to determine the number of pancakes you can make. If you want to make more or less than 5 pancakes, you can use the number of eggs you have to determine the number of pancakes you can make. Assuming you have enough flour and baking powder. Assuming you have enough flour and baking powder.

Relating Pancakes to Making Molecules Mole-to-Mole Conversions The balanced equation is the “recipe” for a chemical reaction. The balanced equation is the “recipe” for a chemical reaction. The equation 3 H 2 (g) + N 2 (g)  2 NH 3 (g) tells us that 3 molecules of H 2 react with exactly 1 molecule of N 2 and make exactly 2 molecules of NH 3 or: The equation 3 H 2 (g) + N 2 (g)  2 NH 3 (g) tells us that 3 molecules of H 2 react with exactly 1 molecule of N 2 and make exactly 2 molecules of NH 3 or: 3 molecules H 2  1 molecule N 2  2 molecules NH 3 Since we count molecules by moles: Since we count molecules by moles: 3 moles H 2  1 mole N 2  2 moles NH 3

Example 8.1: Sodium chloride, NaCl, forms by the following reaction between sodium and chlorine. How many moles of NaCl result from the complete reaction of 3.4 mol of Cl 2 ? Assume there is more than enough Na. Sodium chloride, NaCl, forms by the following reaction between sodium and chlorine. How many moles of NaCl result from the complete reaction of 3.4 mol of Cl 2 ? Assume there is more than enough Na. 2 Na(s) + Cl 2 (g)  2 NaCl(s) Information: Given:3.4 mol Cl2 Find:? moles NaCl Conversion Factor: 1 mol Cl2  2 mol NaCl Solution Map: mol Cl2  mol NaCl Answer= 6.8 moles NaCl

Example Two: According to the following equation, how many moles of water are made in the combustion of 0.10 moles of glucose? According to the following equation, how many moles of water are made in the combustion of 0.10 moles of glucose? C 6 H 12 O O 2  6 CO H 2 O Solution = Solution =

Day #2 Dec 13 th Section 8.3

Warm up 12/13 Worksheet 8.1 # 1 and 3 Worksheet 8.1 # 1 and 3

Making Molecules Mass-to-Mass Conversions We know there is a relationship between the mass and number of moles of a chemical. We know there is a relationship between the mass and number of moles of a chemical. 1 mole = Molar Mass in grams. The molar mass of the chemicals in the reaction and the balanced chemical equation allow us to convert from the amount of any chemical in the reaction to the amount of any other. The molar mass of the chemicals in the reaction and the balanced chemical equation allow us to convert from the amount of any chemical in the reaction to the amount of any other.

Factor Label: Factor Label: = g C 6 H 12 O 6 Information: Given:58.5 g CO 2 Find: g C 6 H 12 O 6 Conversion Factors: 1 mol C 6 H 12 O 6 = g 1 mol C 6 H 12 O 6 = g 1 mol CO 2 = g 1 mol CO 2 = g 1 mol C 6 H 12 O 6  6 mol CO 2 1 mol C 6 H 12 O 6  6 mol CO 2 Solution Map: g CO 2  mol CO 2  mol C 6 H 12 O 6  g C 6 H 12 O 6 mol C 6 H 12 O 6  g C 6 H 12 O 6 Example: How many grams of glucose can be synthesized from 58.5 g of CO 2 in the reaction? 6 CO 2 (g) + 6 H 2 O(l)  6 O 2 (g) + C 6 H 12 O 6 (aq)

Example 2 - How Many Grams of O 2 Can Be Made from the Decomposition of g of PbO 2 ? 2 PbO 2 (s) → 2 PbO(s) + O 2 (g) (Given these formula masses:PbO 2 = 239.2, O 2 = 32.00)

Day 3 Check and Review WS

Warm up 12/14 WS 8.1 #5,7, & 9 WS 8.1 #5,7, & 9

Day 4 Check WS 8.3 Quiz Section

Warm-up 12/15 Have worksheet 8.3 out Have worksheet 8.3 out Get a periodic table, calculator, pencil out Get a periodic table, calculator, pencil out

Day 5 Section 8.5 and 8.6 Limiting reactants

Warm-up 12/16 Given the following reaction, how many grams of silver will be made if 4.3g of silver nitrate were used? Given the following reaction, how many grams of silver will be made if 4.3g of silver nitrate were used? Silver nitrate and copper produce, silver and copper nitrate Silver nitrate and copper produce, silver and copper nitrate

More Making Pancakes We know that: We know that: But what would happen if we had 3 cups of flour, 10 eggs, and 4 tsp of baking powder? 1 cup flour + 2 eggs + ½ tsp baking powder  5 pancakes

More Making Pancakes, Continued

23 More Making Pancakes, Continued Each ingredient could potentially make a different number of pancakes. Each ingredient could potentially make a different number of pancakes. But all the ingredients have to work together! But all the ingredients have to work together! We only have enough flour to make 15 pancakes, so once we make 15 pancakes, the flour runs out no matter how much of the other ingredients we have. We only have enough flour to make 15 pancakes, so once we make 15 pancakes, the flour runs out no matter how much of the other ingredients we have.

More Making Pancakes, Continued The flour limits the amount of pancakes we can make. In chemical reactions we call this the limiting reactant. The flour limits the amount of pancakes we can make. In chemical reactions we call this the limiting reactant. Also known as limiting reagent. Also known as limiting reagent. The maximum number of pancakes we can make depends on this ingredient. In chemical reactions, we call this the theoretical yield. The maximum number of pancakes we can make depends on this ingredient. In chemical reactions, we call this the theoretical yield. It also determines the amounts of the other ingredients we will use! It also determines the amounts of the other ingredients we will use!

Information: Given:0.552 mol Al, mol Cl 2 Find: limiting reactant, theor. yield Conversion Factors: 2 mol AlCl 3  2 mol Al, 2 mol AlCl 3  2 mol Al, 2 mol AlCl 3  3 mol Cl 2 2 mol AlCl 3  3 mol Cl 2 Solution Map: mol each reactant  mol AlCl 3 Example: What is the limiting reactant and theoretical yield when mol of Al react with mol of Cl 2 ? 2 Al(s) + 3 Cl 2 (g) → 2 AlCl 3 Smallest amount Limiting reactant = Al Theoretical yield = mol AlCl 3

Example 2 - How Many Moles of Si 3 N 4 Can Be Made from 1.20 Moles of Si and 1.00 Moles of N 2 in the Reaction 3 Si + 2 N 2  Si 3 N 4 ?

27 More Making Pancakes Let’s now assume that as we are making pancakes, we spill some of the batter, burn a pancake, drop one on the floor, or other uncontrollable events happen so that we only make 11 pancakes. The actual amount of product made in a chemical reaction is called the actual yield. Let’s now assume that as we are making pancakes, we spill some of the batter, burn a pancake, drop one on the floor, or other uncontrollable events happen so that we only make 11 pancakes. The actual amount of product made in a chemical reaction is called the actual yield. We can determine the efficiency of making pancakes by calculating the percentage of the maximum number of pancakes we actually make. In chemical reactions, we call this the percent yield. We can determine the efficiency of making pancakes by calculating the percentage of the maximum number of pancakes we actually make. In chemical reactions, we call this the percent yield.

Theoretical and Actual Yield As we did with the pancakes, in order to determine the theoretical yield, we should use reaction stoichiometry to determine the amount of product each of our reactants could make. As we did with the pancakes, in order to determine the theoretical yield, we should use reaction stoichiometry to determine the amount of product each of our reactants could make. The theoretical yield will always be the least possible amount of product. The theoretical yield will always be the least possible amount of product. The theoretical yield will always come from the limiting reactant. The theoretical yield will always come from the limiting reactant. Because of both controllable and uncontrollable factors, the actual yield of product will always be less than the theoretical yield. Because of both controllable and uncontrollable factors, the actual yield of product will always be less than the theoretical yield.

Measuring Amounts in the Lab In the lab, our balances do not measure amounts in moles, unfortunately, they measure amounts in grams. In the lab, our balances do not measure amounts in moles, unfortunately, they measure amounts in grams. This means we must add two steps to each of our calculations: first convert the amount of each reactant to moles, then convert the amount of product into grams. This means we must add two steps to each of our calculations: first convert the amount of each reactant to moles, then convert the amount of product into grams.

Since the percentage yield is < 100, the answer makes sense. Check: Solution: Example 8.6—When 11.5 g of C Are Allowed to React with g of Cu 2 O in the Reaction Below, 87.4 g of Cu Are Obtained. Cu 2 O(s) + C(s)  2 Cu(s) + CO(g) The smallest amount is g Cu, therefore that is the theoretical yield. The reactant that produces g Cu is the Cu 2 O, Therefore, Cu 2 O is the limiting reactant.

Example 2- —How Many Grams of N 2 (g) Can Be Made from 9.05 g of NH 3 Reacting with 45.2 g of CuO? 2 NH 3 (g) + 3 CuO(s) → N 2 (g) + 3 Cu(s) + 3 H 2 O(l) If 4.61 g of N 2 Are Made, What Is the Percent Yield?

Day 7 Dec 19 th Copper/ Silver Lab

Warm –up 12/19 Have your prelab out and complete. Have your prelab out and complete.

Day 8 Lab WU and Quiz

Day 9 Jan 4 Section 8.7

Enthalpy Change We previously described processes as exothermic if they released heat, or endothermic if they absorbed heat. We previously described processes as exothermic if they released heat, or endothermic if they absorbed heat. The enthalpy of reaction is the amount of thermal energy that flows through a process. The enthalpy of reaction is the amount of thermal energy that flows through a process. At constant pressure. At constant pressure.  H rxn  H rxn

37 Sign of Enthalpy Change For exothermic reactions, the sign of the enthalpy change is negative when: For exothermic reactions, the sign of the enthalpy change is negative when: Thermal energy is produced by the reaction. Thermal energy is produced by the reaction. The surroundings get hotter. The surroundings get hotter.  H = ─  H = ─ For the reaction CH 4 (s) + 2 O 2 (g)  CO 2 (g) + 2 H 2 O(l), the  H rxn = −802.3 kJ per mol of CH 4. For the reaction CH 4 (s) + 2 O 2 (g)  CO 2 (g) + 2 H 2 O(l), the  H rxn = −802.3 kJ per mol of CH 4. For endothermic reactions, the sign of the enthalpy change is positive when: For endothermic reactions, the sign of the enthalpy change is positive when: Thermal energy is absorbed by the reaction. Thermal energy is absorbed by the reaction. The surroundings get colder. The surroundings get colder.  H = +  H = + For the reaction N 2 (s) + O 2 (g)  2 NO(g), the  H rxn = kJ per mol of N 2. For the reaction N 2 (s) + O 2 (g)  2 NO(g), the  H rxn = kJ per mol of N 2.

Enthalpy and Stoichiometry The amount of energy change in a reaction depends on the amount of reactants. The amount of energy change in a reaction depends on the amount of reactants. You get twice as much heat out when you burn twice as much CH 4. You get twice as much heat out when you burn twice as much CH 4. Writing a reaction implies that amount of energy changes for the stoichiometric amount given in the equation. Writing a reaction implies that amount of energy changes for the stoichiometric amount given in the equation. For the reaction C 3 H 8 (l) + 5 O 2 (g)  3 CO 2 (g) + 4 H 2 O(g)  H rxn = −2044 kJ So 1 mol C 3 H 8  5 mol O 2  3 mol CO 2  4 mol H 2 O  −2044 kJ.

Example 8.7—How Much Heat Is Associated with the Complete Combustion of 11.8 x 10 3 g of C 3 H 8 (g)? 1 mol C 3 H 8 = kJ, Molar mass = g/mol 1 mol C 3 H 8 = kJ, Molar mass = g/mol The sign is correct and the value is reasonable x 10 3 g C 3 H 8, heat, kJ Check: Solution: Solution Map: Relationships: Given:Find: mol C 3 H 8 kJg C 3 H 8

Example 2- How Much Heat Is Evolved When a g Diamond Is Burned? (  H combustion = −395.4 kJ/mol C)

Day 10 & 11 Review and Test