Chapter 5 HW

1. #3

2. Chapter 5 HW • 5) • Strategy=

3. #9 • (a) W= Force applied over a distance • (b) W=FD

4. 15 • (a) q is negative because the system loses heat and w is negative because the system does work. • ΔE = q + w = -113kJ + (-39kJ) = -152kJ. The process is exothermic • (b) ΔE = q + w = +1.62kJ - .847kJ=.75kJ. The process is endothermic. • (c) q is positive because system gains heat and w is negative because the system does work. • ΔE = q + w = +77.5 kJ - 63.5kJ=14kJ. The process is endothermic

5. 17 • (a) ΔE = q + w since q is neg and w is positive, ΔE depends on the relative magnitudes of each. • (b) since q is positive and w is positive, ΔE is positive • (c) since q is positive and w is negative, ΔE depends on the relative magnitudes of each.

6. 19 • (a) A state function is a property of a system that depends only on the physical state of the system, not on the route used by the system to get to the current state • (b) Internal energy and Enthalpy are state functions. Work is not a state function • (c) Temp is a state function, regardless of how hot or cold the samples has been, temp only depends on its present condition.

7. See back of book for 23

8. 25 • Since ΔH is negative , the reactants 2Cl(g) have a higher enthalpy.

9. Question 27 • A.) Exothermic (H is negative) B.) C.)

10. 5.27 D • 2 MgO(s) 2Mg(s) + O2(g) • Reversed reaction so sign on H is reversed

11. Question 29(a)

12. Question 29 (b)

13. Question 29 (c)

14. 31 • At constant P, ΔE= ΔH-P ΔV. In order to calc ΔE, mor einfo about the condition must be known. For an ideal gas at constant P and T, P ΔV= ΔnRT must be known to calc ΔE from ΔH.

15. 35 • (a) CO2 (g) + 2H2O (l) → CH3OH (l) + 3/2 O2 (g) ΔH=726.5kJ • (b) 2CH3OH (l) + 3 O2 (g) → 2CO2 (g) + 4H2O (l) ΔH=2(726.5kJ) = -1453kJ • (c) The exothermic reaction is more likely to be favored thermodynamically • (d) Vaporization is endothermic. If the products were gas, less heat energy would be available to release to the surroundings since ti takes energy to convert liquid to gas. It is about 88kJ per 2 moles water. This is not enough to make the overall reaction endothermic.

16. Question 39

17. 41

18. Question 45 (a)

19. Question 45 (b)

20. Question 45 (c)

21. #47 • If a reaction can be described as a series of steps, ΔH for the reaction is the sum of the enthalpy changes for the each step. As long as we can describe a route where we have the ΔH for each step is known, then we can calculate the overall ΔH .

22. 49 • A→B ΔH =+30kJ • B →C ΔH=+60kJ • Then the overall is 90kJ

23. 51

24. 53

25. Question 59

26. Question 61 (a)

27. Question 61 (b)

28. Question 61 (c) • Hrxn=2Hºf Fe2O3 - 4Hºf FeO - Hºf O2 • 2(822.16kJ) - 4(-271.9kJ) - 2(0) = • -556.7kJ

29. Question 61 (d)

30. Question 63 • Hrxn=3Hºf CO2 + 3Hºf H2O - Hºf C3H6O • 3(-393.5kJ) + 3(-285.83kJ) - Hºf C3H6O(l) = -1790kJ • Hºf C3H6O(l)=-248kJ

31. Question 67 (a & b) • C8H18 +25/2O2 8CO2 + 9H2O • 8C + 9H2  C8H18

32. Question 67c • Hrxn=8Hºf CO2 (g)+ 9Hºf H2O(g) - Hºf -25/2 Hºf O2(g)- Hºf C8H18(l) • -5069kJ=8(-393.5kJ) + 9(-241.82kJ) -C8H18(l) -25/2(0) = Hºf C8H18(l) =-255kJ

33. Question 73

34. Question 75(a) • C3H4(g)+4O2(g)3CO2(g)+ 2H2O(g) • H = 3(-393.5kJ) + 3(-241.82kJ) -(185.4kJ) - 4(0)= -1850kJ/molC3H4

35. Question 75 a

36. Question 75b • C3H4(g)+9/2O2(g)  3CO2(g) + 3H2O(g) • H = 3(-393.5kJ) + 3(-241.82kJ) -9/2(0)- (20.4kJ)=-1926kj/molC3H6

37. 75b

38. Question 75c • C3H8(g)+5O2(g3CO2(g)+ 4H2O(g) • H = 3(-393.5kJ) + 4(-241.82kJ) -(-103.8kJ) - 5(0) = • -2044kJ/molC3H8

39. Question 75c

40. Question 100(a) • Mol Cu=M*L=1.00M*0.0500L=0.0500mol • G=mol *M=0.0500*63.546=3.1773=3.18g Cu • Given there is one mole of Cu per mole of compound (CuSO4)

41. 100 ( b & c) • CuSO4 + KOH → K2SO4 + Cu(OH) 2 • Cu 2+ SO4 2- +2K 1+ OH 1- Cu(OH)2 + K 1+ SO4 2- • Cu2++2OH-Cu(OH)2

42. 100(d) • The temp rises so exothermic • Q=(100g)(-6.2ºC)(4.184J/gºC) =-2.6kJ • The reaction is carried out involves .050 mol so on molar basis: • -2.6 kJ/.050mol = -52 kJ/mol