1981 D
Four effects and 4 explanations valued at 1 point each.
a) No, the reactant is favored. Treaction is endothermic and products are at highter energy than the reactant.
b) Yes, products are favored. [delta]S > O as 2 moles of gas are produced form 1 mole of gas.
c) Right, products are favored. For the system at constant pressure: absorption of heat favors the products. An argument using LeChatelier's principle can be used with heat considered as a reactant; or T[delta]S favors products as [delta]G becomes more negative. For the system at constant volume: products are favored but increase in the yield of products results in an increase in pressure which would drive the reaction to the left.
No points were deducted for students who mentioned both the thermodynamic effect and the counteractiong pressure effect at constant volume but were uncertain as to which effect is larger. Students who considered a system at constant volume and stated only that the increase in pressure would drive the reaction to the left received half credit.
d) Left, the reactant is favored. A decrease in the volume would increase the pressure and the strain is relieved by the reverse reaction which produces 1 mole of gas from 2 moles of gas.
1983 B
2)
a) two points
[delta]G° = [sigma] [delta]Gf° (prod) - [sigma] [delta]Gf° (react)
[delta]G° = - 166.2 - (- 137.3 + 2 (0))
[delta]G° = -28.9 KJ/mol
b) two points
[delta]G° = - RT ln K (or - 2.3 RT log K)
- 28.9 = - ( 8.31 x 10¯3) (298) ln K
ln K = 11.67
K = 1.17 x 105
c) two points
[delta]G° = [delta]H° - T [delta]S°
- 28,900 = -128,100 - 298 [delta]S°
[delta]S° = - 99,200 / 298 = - 333 J / mol-K
d) three points
[delta]Hf° (H2) = 0 and [delta]Gf° (H2) = 0
deltaS° = [sigma]S° (prod) - [sigma]S° (react)
- 333 J / mol-K = 126.8 J / mol-K - 197.9 J / mol-K - 2 S° (H2)
S° = 131 J / mol-K
1984 B
Average score 5.52
a) three points
From Hess's law:
[delta]H°f = [4 (393.5) + 4 (205.85)] - 2183.5 kJ = - 533.8 kJ
b) one point
4 C(s) + 4 H2(g) + O2(g) ---> C3H7COOH
c) two points
[delta]S°f butyric acid = S° butyric acid - 4 S° carbon - 4 S° H2 - S° O2
[delta]S°f butyric acid = [226.3 - 4(5.69) - 4(130.6) - 205] joules/K = - 523.9 joules/K
Note: If part c was based on the equation in part b, and was done correctly, credit was given for part c even if part b was wrong.
d) three points
[delta]G°f butyric acid = [delta]H°f - T [delta]S°f
[delta]G°f = [- 533.9 - (298) (- 0.524)] kJ
[delta]G°f= - 377.7 kJ
Note: For each of the problems, a maximum of one point was subtracted for gross misuse of significant figures and. or for a mathematical error if correct principles were used.
1992 B
3) average = 3.5 (Only 30 scores of nine; kids did not see stoichiometry in (b), had problems on which gas constant to use, and a hard time in (c) in relating a more negative value.)
a) two points [delta]G° = - RT ln K; rearranging gives ln K = [delta]G° ÷ - RT ln K = - 123,000 J ÷ - ((8.31 J/mol K) (298 K)) = 49.7 K = 3.72 x 1021
b) two points
[delta]G° = [delta]H° - T[delta]S°
- 246,000 J = - 326,400 J - (298) (x)
x = - 270 J / K
c) two points
[delta]S is a larger negative number
ClF3 (liquid) is more ordered (less disordered) than ClF3 (gas)
This was my answer before I saw the standard given above: A liquid is more ordered than a gas. There would be a greater entropy change in gas + gas ---> liquid than in gas + gas ---> gas. Therefore, sign is the same, but absolute magnitude is greater.
d) three points
i) ClF3 is a more complex molecule (i.e. more atoms) with more vibrational and rotational degrees of freedom than Cl2
ii) Cl2 + 3 F2 ---> 2 ClF3; use Hess's Law
[sigma]Srxn = [sigma]S products - [sigma]S reactants
- 270 = [2 (281.50)] - [222.96 + 3x]
x = 203 J mol¯1 K¯1
1997D
(a) DS° is positive (or "+", or ">0") 1 point
Moles products > moles reactants 1 point
Note; all species are gaseous, so (g) need not be indicated. To earn credit, number of particles (moles) must be discussed. No explanation point earned for just nothing that disorder increases, or that PCl5 is decomposing or dissociating.
(b) DG° will decrease (or become more negative, or become smaller). 1 point
DG° = DH° - TDS°
and since DS° is positive, TDS° is positive ( > 0). Thus increasing T will result in a larger term being subtracted from DH°, or, DG° = -RT ln K and K is going up in value since T is increasing.)
Note: full credit earned for part (b) if:
DS° < 0 in part (a) which leads to DG° is increasing because TDS° is added to DH°, or,
DS° = 0 in part (a) which leads to no change in DG°
(c) no change (one point)
PHe is not part of the a) reaction (He is not involved) or, b) law of mass action or, c) reaction quotient or, d) equilibrium constant expression; one point
hence altering PHe has no effect on the position at equilibrium
(d) moles of Cl2 will decrease (one point)
The decrease in volume leads to an increase in pressure (concentration), therefore the reaction shifts to the left because:
(one point for any of the following)
Q > Ksp (Q > Kc, or,
the rate of the reverse reaction increase more than the rate of the forward reaction, or,
the reaction shifts toward the lesser moles of gas.
Note: "LeChatelier's principle" alone is not sufficient to earn the explanation point. If response suggests that the number of moles of Cl2 is halved because the system is "cut" in half, only one point is earned.