Stoichiometry

1. Stoichiometry Molar relationships in chemical reactions

2. 3.1 Chemical Equations:A Review • Law of conservation of mass • Relationship between reactant and products produces a balanced chemical equation • Reactants  Products A + B  C + D • Balancing chemical eqns

3. Balancing Chemical Equations • Must have correct chemical formulas • Change coefficients as needed to balance equation • Do not change subscripts of chemical formulas • Indicate physical states by writing in parentheses (s), (l), (g), (aq) • Begin with an element that appears in only one reactant and product • If possible, do not begin with O or H

4. Balancing Chemical Equations • ____ N2 + ____ H2 ____ NH3 • ____ KClO3  ____ KCl + ____ O2 • ____ NaCl + ____ F2  ____ NaF + ____ Cl2 • ____ H2 + ____ O2  ____ H2O • ____ Pb(OH)2 + ____ HCl  ____ H2O + ____ PbCl2 • ____ AlBr3 + ____ K2SO4  ____ KBr + ____ Al2(SO4)3 • ____ CH4 + ____ O2  ____ CO2 + ____ H2O • ____ C3H8 + ____ O2  ____ CO2 + ____ H2O • ____ C8H18 + ____ O2  ____ CO2 + ____ H2O • 10) ____ FeCl3 + ____ NaOH  ____ Fe(OH)3 + ____NaCl

5. Balancing Chemical Equations • ____ P + ____O2  ____P2O5 • ____ Na + ____ H2O  ____ NaOH + ____H2 • ____ Ag2O  ____ Ag + ____O2 • ____ S8 + ____O2  ____ SO3 • ____ CO2 + ____ H2O  ____ C6H12O6 + ____O2 • ____ K + ____ MgBr  ____ KBr + ____ Mg • ____ HCl + ____ CaCO3  ____ CaCl2 + ____H2O + ____ CO2 • ____ HNO3 + ____ NaHCO3  ____ NaNO3 + ____ H2O + ____ CO2 • ____ H2O + ____ O2  ____ H2O2 • 20) ____ NaBr + ____ CaF2  ____ NaF + ____ CaBr2

6. 3.2 Patterns of Chemical Reactivity • Because groups of elements have similar chemical behavior, the periodic table can be used to predict reactions involving elements • Example: Na (s) + H2O (l) NaOH (aq) + H2(g) • Alkalai metals + water  metal hydroxides + H2

7. Types of Chemical Reactions • Synthesis (Combination) reactions • Two or more substances combine to form a new substance • Often involve elements combining to form a compound • A + B  C 4Na (s) + O2 (g)  2Na2O (s) sodium oxide

8. Types of Chemical Reactions • Decomposition reactions • A single substance breaks down into two or more smaller substances • A  B + C H2CO3 (aq)  CO2 (g) + H2O (l) carbonic acid

9. Types of Chemical Reactions • Combustion reactions • Hydrocarbons + O2 CO2 + H2O • Cpds containing C, H, O  CO2 + H2O • Involve… • O2 as reactant • Release of heat & light • Often H2O is a product

10. 3.3 Formula Weights • Atomic mass unit (amu) • A unit invented to describe extremely small masses • Defined as 1/12 the mass of an atom of 12C • 1 amu = 1.66054 x 10-24 g

11. Average Atomic Masses • Atomic masses given on the PT are weighted averages of all the isotopes of that element • Equals the sum of the products of the (mass) x (frequency) of the isotopes • mavg = Σ (m1f1) + (m2f2) + (m3f3) + …..

12. Average atomic mass • mavg = Σ (m1f1) + (m2f2) + (m3f3) + ….. • Example • Chlorine occurs as two isotopes: • Isotope amu freq (m x f) • 35Cl 34.964 75.53% 26.41 • 37Cl 36.966 24.47% +9.05 • Atomic mass of chlorine = 35.46

13. Formula & Molecular Weights • Formula mass refers to ionic cpds • Molecular mass refers to covalent cpds • Is the sum of atomic masses of the molecule Calculate mol mass of Ca (NO3)2

14. Percent Composition of Formulas • Percentage by mass contributed by each element in the formula

15. Percent Composition • Determine the % composition of all elements in sucrose, C12H22O11 • %C = (12 x 12) / 342 = 42.0% • %H = (1 x 22) / 342 = 6.4% • %O = (16 x 11) / 342 = 51.6%

16. 3.4 The Mole • Is a counting unit • Avagadro’s number = 6.022 x 1023 • Interconvert between moles & particles • Molar mass = the mass of one mole of a substance • Molar mass of elements = atomic mass in grams

17. Converting between particles, moles, and grams • Particles and grams cannot be interconverted directly. • The mole is the bridge between particles and grams.

18. 3.5 Empirical Formula Analysis • To determine empirical formula from percent composition data • Empirical formula gives simplest ratio of atoms in a compound • Therefore, always convert to moles when calculating empirical formulas • Sample exercise 3.13

19. Combustion Analysis • Determines empirical formula based upon analysis of products of combustion • Example: 18.4 g of a compound of CHO produced 41.7 g CO2 and 19.65 g H2O • CxHyOz + O2 CO2+ H2O 18.4 g 41.7g 19.65 g • All carbon in CO2 came from the CHO • All hydrogen in H2O came from CHO

20. Combustion Analysis • Determine amt of C in CHO by determining amt of C in the CO2 produced. %C in CO2 x g CO2 = g C in CHO .2729 x 41.17 = 11.23 g C = 0.935 mol C

21. Combustion Analysis 2. Determine amt of H in CHO by determining amt of H in the H2O produced. %H in H2O x g H2O = g H in CHO .1119 x 19.65 = 2.20 g H = 2.18 mol H

22. Combustion Analysis • Determine amt of O in CHO by determining amt of H in the H2O produced • By law of conservation of mass, grams of CHO = gC + gH + gO • So grams O = grams CHO – gC – gH • 18.40 – 11.23 – 2.20 = 4.97 gO = .311 mol O • Mole ratio C 0.935 H 2.18 O 0.311 • Empirical formula C3H7O

23. 3.6 Quantitative Information from Balanced Equations • Balanced chemical equations are like specific recipes • Balanced equations tell us …. • the relative amounts of reactants (ingredients) • the relative amounts of products • other relevant conditions needed (e.g. heat) • The unit of measure in a balanced equation is the mole • Indicated by coefficients

24. Apple Snapple Oatmeal(www.MrBreakfast.com) Apple Snapple Oatmeal(4 servings) 1 medium apple or pear 3 cups apple juice or cider 1 and 1/3 cups regular rolled oats 1/4 cup raisins or chopped pitted dates 1/4 teaspoon ground cinnamon milk (if you like) brown sugar (if you like)

25. Stoichiometric Calculations The coefficients in the balanced equation give the ratio of moles of reactants and products.

26. 3.6 Quantitative Information from Balanced Equations • Mole ratio used to calculate actual molar amounts in a balanced eqn • Sample Problem 3.16 • Determine mass of water produced from combustion of 1.00 g glucose • C6H12O6 + __ O2 __ CO2 +__ H2O • C6H12O6 + 6 O2 6 CO2 + 6 H2O

27. Solving Stoichiometry Problems

28. Sample problem • Determine mass of water produced from combustion of 1.00 g glucose • C6H12O6 + 6 O2 6 CO2 + 6 H2O • Determine moles glucose • Determine moles water • Determine grams water

29. 3.7 Limiting Reactants • Stoichiometrically least abundant reactant • Completely consumed in the reaction • Determines theoretical yield of the reaction • When all reactants are present in stoichiometric amounts, all are limiting reagents

30. Limiting Reactants • The limiting reactant is the reactant present in the smallest stoichiometric amount. • In other words, it’s the reactant you’ll run out of first (in this case, the H2).

31. Limiting Reactants In the example below, the O2 would be the excess reagent.

32. Limiting Reagents • How many moles of ammonia can be produced when 3.0 mol nitrogen and 6.0 mol of hydrogen are permitted to react? • Write & balance the equation • Determine the LR to determine yield • Reactant  least yield is the LR • What is the excess reagent? How much is left over?

33. Theoretical & Actual Yields • Theoretical Yield • Quantity of product produced when 100% of limiting reagent reacts • Determined from balanced equation • Actual Yield • Quantity of product actually produced • No reaction is 100% efficient, therefore…. • Theoretical Yield does not equal Actual Yield

34. Sample Problem 3.20 • 2 C6H12 + 5 O2 2 H2C6H8O4 + 2 H2O • Given 25.0 g cyclohexane and excess oxygen, determine theoretical yield of adipic acid

35. Percent Yield • Expresses the efficiency of a reaction • Is ratio of actual yield to theoretical yield • Percent Yield = Actual Y/ Theroretical Y %Y = AY / TY

36. Sample Problem 3.20 (cont) • 2 C6H12 + 5 O2 2 H2C6H8O4 + 2 H2O • Theoretical yield = 43.5 g adipic acid (from first part) • If actual yield of adipic acid was 33.5 g, determine percent yield of reaction • %Y = Actual yield / Theoretical yield • %Y = 33.5g/43.5g = .77 = 77%