CHEM 1412 Problem Set #3a



CHEM 1412 Problem Set #3a Dr. Ya-Ping Huang

Solubility Equilibrium

1. Calculate the molar solubility of CaF2 at 25oC in:

a. pure water (2.1 x 10-4 M)

b. in 0.010M Ca(NO3)2 solution (3.1 x 10-5 M)

c. in 0.010M KF solution (3.9 x 10-7 M)

[Ans]: The 1st step is to write the equation for dissolution, and find the relationship between Ksp and molar solubility.

. a. R CaF2(s) ( Ca2+(aq) + 2F-(aq) Let S represent the molar solubility

E S ( S 2S

Ksp = [Ca2+]eq [F-]eq2 = (s)(2s)2 = 4S3 = 3.9x10-11

[pic]

b. In 0.010M Ca(NO3)2 solution, there is the common –ion effect. The extra Ca2+ from Ca(NO3)2 will

reduce the solubility of CaF2(s) (Le Chatelier’s principle) –the common-ion effect

R CaF2(s) ( Ca2+(aq) + 2F-(aq) Let S represent the molar solubility

E S ( S 2S

+0.010

[Ca2+]eq = 0.010+ S [F-]eq = 2S

Ksp = [Ca2+]eq [F-]eq2 = (S+0.010)(2S)2 ( (0.010)(2S)2 = 0.04S2 = 3.9x10-11

(s is dropped from s+0.010, because when there is common-ion effect , the solubility will

be severely reduced such that the s term is negligible compared to the concentration of

commen-ion)

[pic]

Ksp = [Ca2+]eq [F-]eq2 = (s)(2s)2 = 4S3 = 3.9x10-11

c. in 0.010M KF solution: there is the common –ion effect. The extra F- from KF will reduce the

solubility of CaF2(s) through common-ion effect (Le Chatelier’s principle)

R CaF2(s) ( Ca2+(aq) + 2F-(aq) Let S represent the molar solubility

E S ( S 2S

+0.010

[Ca2+]eq = S [F-]eq = 0.010+ 2S

Ksp = [Ca2+]eq [F-]eq2 = (S)(0.01+2S)2 ( (S)(0.01)2 = 1.0x10-4S = 3.9x10-11

S = Ksp/1.0x10-4 = 3.9x10-7 M

2. Calculate the molar solubility of BaSO4 at 25oC:

a. in pure water

b. in 0.10M Na2SO4 solution

c. Grams of BaSO4 dissolved in 2.0 Liters of water

e. LD50 of Ba2+ for rat is around 20 mg/Kg body weight of rats. Would the Ba2+ in part (d) dangerous if

ingested? (1.05 x 10-5M, 1.1 x 10-9 M, 4.9 x 10-3 g, 2.16 mg)

[Ans]:

a. In pure water (no common-ion or other effects)

BaSO4(s) ( Ba2+(aq) + SO42-(aq)

Let S represent the molar solubility, then [Ba2+] = S and [SO42-] = S

Ksp = [Ba2+] [SO42-] = (S)( S)= S2 = 1.1x10-10 S=[pic]

b. in 0.10M Na2SO4 solution, the additional SO42- ions from Na2SO4 will reduce solubility of BaSO4

through common-ion effect

Ksp = [Ba2+] [SO42-] = (S)(0.10+S)= S(0.10) = 1.1x10-10 S=1.1x10-9 M

d. mg of Ba2+ in 1.5 L of saturated BaSO4 solution.

mg of Ba2+ = (M)(V)(MM) = [pic]

e. LD50 refers to lethal dose for 50% population exposed. Assume a typical adult weighs 50kg, then

LD50 = (20mg/Kg body weight)(50 kg) = 1000mg. So 2.16 mg is quite safe.

3. How would the solubility of the following substances be affected by ( pH of a solution?

a. Ni(OH)2 b. CaCO3 c. BaSO4 d. AgCl

[Ans]: The key to see how does ( pH of a solution affect the solubility is to see if additional H+ will affect

the dissolution process

| | |Dissolution reaction |Rexn w/ H+ |dissolution |solubility |

|A |Ni(OH)2 (s) |Ni(OH)2 (s) ( Ni2+(aq) + 2OH-(aq) |H+ + OH- ( H2O |( |( |

|B |CaCO3 |CaCO3( Ca2+(aq) + CO32- |2H++CO3 2-( H2O + CO2 |( |( |

|C |BaSO4 |BaSO4(s) ( Ba2+(aq) + SO42-(aq) |H++SO42-(HSO4- |Slightly favored |(barely |

|d |AgCl |AgCl( Ag+(aq) + Cl-(aq) |No reaction |Not affected |same |

4. A solution is 0.10 M in and the pH is adjusted to 8.0. Would Mg(OH)2 precipitate? (No)

[Ans]: Calculate Qsp of Mg(NO3)2

Mg(OH)2(s)( Mg2+ + 2OH Ksp = 1.5x10-11

Qsp = [Mg2+][OH-]2 = (0.10)(1.0x10-6)2 = 1.0x 10-13 Qsp < Ksp, no ppt

5. A solution is 0.10M in Mg(NO3)2. What concentration of OH- is required to just start precipitation of

Mg(OH)2? If NH3-NH4+ buffer is used to control the pH, and [NH3] = 0.10 M. What concentration

of NH4+ is required to prevent the precipitation of Mg(OH)2? (1.2 x 10-5M, >0.15 M)

[Ans]: To find out conditions for ppt, compare the requirements for different situation:

The easiest way is to calculate conditions for saturated solution and modify condition for different

situation

| |Saturated soln, equilibrium |Unsaturated soln, |ppt |

| | |no ppt | |

|Qsp = [Mg2+][OH-]2 |= Ksp = 1.5x10-11 |< Ksp |> Ksp |

|[OH-] |1.2x10-5 M |< 1.2x10-5 M |> 1.2x10-5 M |

|[NH4+] |0.15M |> 0.15 M, need more CA (NH4+] to keep |< 0.15M, need less CA (NH4+] to |

| | |solution acidic |keep solution basic |

For saturated solution, Qsp = [Mg2+] [OH-]2 (0.10) [OH-]2 = 1.5x10-11

[OH-] = [pic]

If [OH-] is maintained by buffer: you can either use Handerson-Hasselbalch equation or Kb of NH3

Kb of NH3 will be more straight forward:

NH3 + H2O ( NH4+ + OH- Kb=[pic] [pic]

[pic]

7. Solid AgNO3 is slowly added to a solution that is 0.0010M in NaCl, NaBr and NaI. Calculate the [Ag+] required to initiate the ppt of each silver salt. Assume the solution volume does not change in the process. (AgCl, requires [Ag+] = 1.8 x 10-7M, AgBr: [Ag+] = 3.3 x 10-10M, AgI: [Ag+] = 1.5 x 10-13M)

[Ans]; For each ppt, 1st calculate the [Ag+] required for saturation.

All 3 ppts (AgCl, AgBr, AgI) follow the same dissolution process:

AgX(s) ( Ag+(aq) + X-(aq) (X= Cl, Br or I)

In saturated solutions, Qsp = [Ag+]eq [X-]eq = Ksp [Ag+]eq = [pic]

| |X |Ksp |[Ag+]eq=[pic] |Order of ppt |

|AgCl |Cl |1.8x10-10 |1.8x10-7 M |3rd, requires most amt of Ag+ |

|AgBr |Br |3.3x10-13 |3.3x10-10 M |2nd, requires 2nd amt of Ag+ |

|AgI |I |1.5x10-16 |1.5x10-13 M |1st, requires least amt of Ag+ |

** Since all three ppts have the same ion ratio, the Ksp indicates the relative molar solubility

AgI has lowest Ksp, therefore the lowest molar solubility, will be the 1st to ppt

AgCl has highest Ksp, therefore the highest molar solubility, will be the last to ppt

8. Solid AgNO3 is slowly added to a solution that is 0.0010M in NaCl and Na2CrO4. Which one will ppt

first, AgCl or Ag2CrO4? Calculate the [Ag+] required to initiate the ppt of each silver salt.

(AgCl 1st, requires [Ag+] = 1.8 x 10-7, Ag2CrO4 requires [Ag+] = 9.5 x 10-5)

[Ans]:

AgCl and Ag2CrO4 have different ion ratio, values of Ksp does not indicates the relative molar solubility

| |Ion ratio |Ksp |Ksp and conc [Ag+]eq=[pic] |[Ag+]eq = |Order of ppt |

|AgCl |1:1=1 |1.8x10-10 |Ksp= [Ag+]eq [Cl-]eq |[pic] |1st, requires less Ag+ |

|Ag2CrO4 |2:1 = 2 |9.0x10-12 |Ksp=[Ag+]2eq [CrO42-]eq |[pic] |2nd, requires more Ag+ |

9. Refer to problem 7, what is [Cl-] and [I-] when AgBr just starts to precipitate?

([Cl-] = 0.001, [I-] = 4.5 x 10-7 when AgBr starts to ppt.

[Ans]: When AgBr starts to ppt, [Ag+ ] = 3.3x10-10 M.

AgCl has not ppt’d yet. All Cl- remains in solution. [Cl-] = 0.001M

AgI ppt’d before AgBr starts to ppt. Once pptn starts, the Qsp of the compound that has ppt’d

always equals to its Ksp.

[pic]

10. A 0.010 M solution of AgNO3 is made 0.50 M in NH3 and Ag(NH3)2+ complex forms.

Ag+(aq) + 2 NH3(aq) ( Ag(NH3)2+(aq) Kf = 1.7 x 107.

a. What is the equilibrium concentration of Ag+ in the solution? (2.56 x 10-9 M)

b. What % of the total silver is in the form of Ag+ (aq)? (2.56 x 10-5 %)

[Ans]:

A, use RICE

R Ag+(aq) + 2 NH3(aq) ( Ag(NH3)2+(aq) Kf = 1.7 x 107.

I 0.010 0.50 0

C -x -2x +x

E (0.01-x) 0.5-2x x

[pic]

You can either solve the math equation or make some assumption to simplify the solution.

Since K is very large, we can assume reaction is near 100%. All limiting reagent Ag+ will be used up.

Let x = 0.01 and reset the RICE:

R Ag+(aq) + 2 NH3(aq) ( Ag(NH3)2+(aq) Kf = 1.7 x 107.

I 0.010 0.50 0

C -0.01 -0.02 +0.01

E (0 0.48 0.01

New equation to solve is

[pic] [Ag +] = x= 2.56x10-9M

b. % of the total silver is in the form of Ag+ (aq) [pic]

Since complex formation reduces % Ag+ to extremely low level, solubility of AgCl will be significantly increased

Problem Set 3b. Thermodynamics

Q1. 1.000g C2H5OH(ℓ) burned in bomb calorimeter, heat capacity = 2.71kJ/(C

[Ans]: C2H5OH(ℓ) + 3 O2(g) ( 2CO2(g) + 3H2O(ℓ) (n = 2-3 = -1

qH2O = (SH)H2O(m)H2O(ΔT)H2O = (4.184kJ/kg oC.)(3.000kg)(1.941 oC)= 24.36 kJ

qcal = Ccal(ΔT)cal = Ccal(ΔT) H2O = (2.71 kJ/ oC)(1.941 oC) = 5.26 kJ

qrxn= qethanol = nethanol (ΔE) ethanol = (1.000g/46.07) (ΔE) ethanol

qtotal = qH2O + qcal + qrxn = 24.36 kJ + 5.26 kJ + qrxn

qrxn = -29.62 kJ = (0.02171 mol) (ΔE) ethanol (ΔE) ethanol = -1364.3 kJ/mol

(H = (E + (nRT = -1364.3 kJ/mol + (-1)(8.314E-3)(298.15K)= -1364.3 -2.48 = -1366.8 kJ/mol)

Q2. A 50.0 mL sample of 0.400M copper (II) sulfate solution at 23.35 oC is mixed with 50.0 mL sample of 0.600M NaOH solution, also at 23.35 oC in a coffee cup calorimeter (heat capacity = 24.0J/oC). After the reaction, the temperature of the resulting mixture is measured to be 26.65 oC. The density of the final solution is 1.02 g/mL. Calculate the amount of heat evolved and (H. (1.49 x 103J, -99.2 kJ/mol rxn)

Write the thermochemical equation for the reaction)

[Ans]: CuSO4(aq) + 2NaOH(aq) ( Cu(OH)2(s) + Na2SO4(aq) (H= -99.2 kJ/mol rxn)

qH2O = (4.184 J/goC)(100 mL)(1.02 g/mL)(26.65 – 23.35oC) = 1408 J

qCal = (24.0 J/oC)(26.65 – 23.35oC) = 79.2 J

(Total heat evolved = qH2O + qCal = 1487 J)

qtotal= qH2O+ qCal+ qrexn = 0

qrexn = -1487 J = n(H

To find n, you have to find moles of each reagent and find the limiting reagent.

mol of CuSO4 = (0.400M)(0.050L) = 0.020 mol[pic]

mol of NaOH = (0.600M)(0.0500L) = 0.030 mol x [pic]

So NaOH is limiting reagent, and n = 0.0150 mole reaction

qrexn = -1487 J = n(H = (0.0150 mole reaction) (H

(H = -1487 J/(0.0150 mole reaction) = - 99133 J/mole rexn = -99.13 kJ/mole rexn

Complete thermochemical equation includes balanced chemical equation and (H

CuSO4(aq) + 2NaOH(aq) ( Cu(OH)2(s) + Na2SO4(aq) (H = -99.13 kJ/mol rxn

Hess’s law

(3). Find (H for the rxn: 2HCl(aq) + F2(g) ( 2HF(aq) + Cl2(g) (-988.8 kJ/mol rxn)

Given the following enthalpies of reaction:

4HCl(aq) + O2(g) ( 2H2O(ℓ) + 2 Cl2(g) (H= -148.4 kJ/mol rxn)

HF(ℓ) ( ½ H2(g) + ½ F2(g) (H= +600.0 kJ/mol rxn

H2(g) + ½ O2(g) ( H2O(ℓ) (H= -285.4 kJ/mol rxn

Q4. The thermite reaction, used for welding iron, is as following:

8 Al(s) + 3Fe3O4(s) ( 9 Fe(s) + 4Al2O3(s)

A. To calculate (H, the best method is using (Hf:

8 Al(s) + 3Fe3O4(s) ( 9 Fe(s) + 4Al2O3(s)

(H( = 9(H(f, Fe(s) + 4 (H(f,Al2O3(s) – 3 (H(f,Fe3O4(s) –8 (H(f, Al(s)

= 4(-1676) – 3(-1118) = -3350 kJ/mol rxn

B. To find the energy released, given both reactants, it’s a limiting reagent type of problem. The approach is to calculate the energy released by the reaction of each reactant. The smaller value is the answer.

a. (H based on 8.0 g Al(s):

[pic]

b. (H based on 20.0 g Fe3O4

[pic]

The answer is therefore 96.3 kJ released. And Fe3O4(s) is the limiting reagent.

c. Grams of Fe produced is based on the limiting reagent Fe3O4(s)

[pic] Fe3O4 [pic]

Q5. Use the standard enthalpy of formation and bond energy to calculate (H for burning of 1mole of

ethyl alcohol, C2H5OH(ℓ). (- 1367, -1022 kJ/mol rxn )

[Ans]: C2H5OH(ℓ) + 3 O2(g) ( 2CO2(g) + 3H2O(ℓ)

(H° = ((Hf°,RHS - ((Hf°,LHS = 2(Hf°,CO2(g) + 3(Hf°,H2O(g) – ((Hf°,C2H5OH(l) + 3(Hf°,O2(g))

= 2 (-393.5) + 3(-285.8) – (-277.7 + 3x0) = -1644.4 – (-277.7)= -1366.7

To calculate with bond energy, you need to write the Lewis structure

H-C-C-O-H + 3 O=O ( 2 O=C=O + 3 H-O-H ( + 4 missing C-H bonds from C2H5OH)

(H° = (BE of LHS - (BE of RHS = 5 C-H + C-C + C-O + O-H + 3 O=O –(4 C=O + 6 O-H)

= 5 (414)+ 347 + 351 + 464 + 3x498 –(4x741 + 6x464)

= 4726 – 5748 = -1022 kJ/mol rxn

Q7. Estimate (G° and determine if the following reaction is spontaneous at 25, 1000 and 2000°C?

N2(g) + O2(g)( 2NO(g)

[Ans]: (G° = (H° - T(S°

(H° = ((Hf°,RHS - ((Hf°,LHS = 2(Hf°,NO(g) – ((Hf°N2(g) + (Hf°,O2(g))

= 2(90.25) – (0+0) = 180.5 kJ/mol rxn

(S° = (S°,RHS - (S°,LHS = 2S°,NO(g) – ((Hf°N2(g) + (Hf°,O2(g))

= 2(210.7) – (191.5 + 205) = 24.9 J/K.mol rxn = 24.9x10-3 kJ/K.mol rxn

(G° = (H° - T(S°

At 25°C (298.15 K) (G° = 180.5 kJ/mol rexn –(298.15)( 24.9x10-3 kJ/K.mol rxn)

= 173.08 kJ/mol rxn (non-spontaneous)

At 1000°C (1273 K) (G° = 180.5 kJ/mol rexn –(1273)( 24.9x10-3 kJ/K.mol rxn)

= 148.80 kJ/mol rxn (non-spontaneous)

At 2000°C (2273 K) (G° = 180.5 kJ/mol rexn –(2273)( 24.9x10-3 kJ/K.mol rxn)

= 123.90 kJ/mol rxn (non-spontaneous)

At 25°C (298.15 K) (G° can be calculated by (GHf°

(G° = ((Gf°,RHS - ((Gf°,LHS = 2(Gf°,NO(g) – ((Gf°N2(g) + (Gf°,O2(g))

= 2(86.57) –(0+0) = 173.14 kJ/mol rxn, almost identical to the one

calculated by (G° = (H° - T(S°

Transition temperature, Ttransition = [pic]

CHEM 1412 Solubility and Precipitation Reaction Dr. Ya-Ping Huang

| |1. Mg(OH)2 |2. Ag3PO4 |3. Fe4[Fe(CN)6]3 |

|a. reaction for |Mg(OH)2(s)( Mg2+ + 2OH- |Ag3PO4(s) ( 3Ag+ + PO43- |Fe4[Fe(CN)6]3( 4Fe3+ |

|dissolving | | |+ 3 [Fe(CN) 6] 4- |

|(dissolution) | | | |

|b. Algebraic |Ksp = S(2S)2=4S3= 1.5x10-11 |10 Ksp = (3S)3S=27S4 = 1.3x10-20 |11 Ksp = (4S)4(3S)3 = 6912 S7 |

|expression of Ksp and |S= molar solubility | |= 3.0 E-41 |

|(S) | | | |

|c. Molar solubility |S=[pic] |S=[pic] |S=[pic] |

|d. Molar mass |58.33 |418.58 |859.24 |

|e. Solubility, g/L |1.55x10-4M)(58.33g/mol)= 9.04 x10-3 g/L |1.96 E-3 |3.95 E-4 |

|f. g in 2.50 L sat’d |M.V.MM = |0.0049 g |9.9 x10-4g |

|solution |(1.55x10-4M)(2.5L)(58.33g/mol)= 0.0226g | | |

|g. |given solution |0.10 M HCl |in 0.1 M AgNO3 |skip |

| |Possible |WB + SA, 100 % neutralization |Common-ion (Ag+) effect on solubility of | |

| |reaction or |Mg(OH)2 + 2H+(Mg2++ 2H2O |Ag3PO4(s) | |

| |effect | | | |

| |Molar solubility|½ (.10MH+)=.05M (solubility determined by the |Ksp = (3S+0.1)3 S |skip |

| | |neutralization) |= 1x 10-3 S S= 1.3 E-17 M | |

Q1g, WB-SA neutralization between HCl and Mg(OH)2 would be 100%. So the moles of Mg(OH)2

neutralized by HCl is the molar solubility. Since HCl is the limiting reagent in the

neutralization, moles of Mg(OH)2 dissolved is ½ of mole of HCl used.

Given the combination of solutions,:

(25.0 mL 0.010M of 1st solution and 50.0 mL 0.020 M 2nd solution)

After dilution, [Solution1] = 0.010M(25.0mL)/75.0mL = 0.0033M,

[Solution2] = 0.020M(50.0mL)/75.0mL = 0.013M

|Solution combination |4. Cu(NO3)2 + NaOH |5. CaCl2 + Na3PO4 |6. AgNO3 + K2CrO4 |

| reaction |Cu(NO3)2 + 2 NaOH ( |3CaCl2 +2 Na3PO4 ( |2AgNO3 + K2CrO4 ( |

| |Cu(OH)2 + 2 NaNO3 |Ca3(PO4)2(s) + 3 NaCl |Ag2CrO4(s) +2 KNO3 |

|a. formula of ppt |Cu(OH)2 |Ca3(PO4)2 |Ag2CrO4 |

|b. Ksp of the ppt |1.6x10-19 |1.0x10-25 |9.0x10-12 |

|c. Qsp in solution |(0.0033)(0.013)2 =5.57x10-7 |(0.0033)3(0.013)2 |(0.0033)2(0.0133) =1.41x10-7 |

| | |= 6.07x10-12 | |

|d. Will ppt form? |Yes |yes |yes |

Thermodynamics Worksheet Dr. Ya-Ping Huang

| |Reactions |1. Decomposition of a fertilizer |2. Habor process |3. Ionization of water |

| | |2NH4NO3(s) ( |N2(g) + 3H2(g) ( 2NH3(g) |H2O(ℓ) ( H+ (aq) + OH-(aq) |

| | |2N2(g) + 4H2O(g) + O2(g) | | |

|a |(H( kJ/ mol rxn |-236 |-92.22 /mol rxn |55.8 kJ/mol rxn |

|b | qp for 500 g (kJ) |NH4NO3(s) -737.5 |NH3(g) -1353 kJ |H2O(ℓ): 1550 kJ |

|c | (n |7 |-2 |0 |

|d |(E( kJ/ mol rxn |-253.35 |-87.26 kJ/mol rxn |55.8kJ/mol rxn |

|e | (S( kJ/mol.K |1.0406 |-0.1987 kJ/mol.K |-0.0806 kJ/mol.K |

|f | Transition Temp |Does not exist |= 464.1 K = 190.9 (C |Does not exist |

|25( C |

|g |(G( kJ/mol rxn |-546.1 |**a. -40.0 (by (H( & (S() |79.82 kJ |

| | | |b. -32.38 ((Gf() | |

|h | Keq |4.53 x 1095 |a.1.0 x 107 |1.04 x 10-14 |

| | | |b. 4.7 x 105 | |

|i |Spontaneous? |yes |yes |pH value for pure water: 6.99 |

|300( C |90( C |

|j |(G( kJ/mol rxn |-832.47 |21.64 kJ/mol rxn |85.06 kJ |

|k |Keq |7.08 x 1075 |0.0107 |5.78 x 10-13 |

|l |Spontaneous? |yes |No |pH value for pure water; 6.12 |

** There is discrepancy in (G( calculated by (Gf( and by (G( = (H( -T (S( for this reaction (2) at 25( C

(1). 2NH4NO3(s) ( 2N2(g) + 4H2O(g) + O2(g) always spontaneous

(H( = 2(Hf(N2(g) + 4(Hf(H2O(g) + (Hf(O2(g) - 2(Hf(NH4NO3(s) = 2(0) +4(-241.8) + 0 –2(-365.6)

= -236 kJ/mol rxn

n = [500g/(80)]/2 = 3.125 mole reaction

q = 3.125 mol rxn x (-236 kJ/mol rxn) = -737.5 kJ

(H( = (E( +(nRT,

(E( = (H( -(nRT = -236 kJ – (7)(8.314E-3)(298.15) = -737.5 kJ –17.35 = -253.35 kJ

Ttran = (H(/(S( = -236 kJ/1.0406kJ/mol.K = -227 K, does not existent,(Transition temperature does not exist

if T< 0 K.)

(In this reaction, reaction is always spontaneous, favored by lower enthalpy, (H( < 0

and increased entropy, (S(> 0)

25( C :(G( = (H( -T (S( = -236kJ – 298(1.0406) = -546.1 kJ/mol rxn

(G( = -5.709logK logK = (G( /( -5.709) = -546.1/-5.709 = +95.66, K = 10exp(+95.66) = 4.53 x 1095

300( C :(G( = (H( -T (S( = -236 – (300+273)(1.0406) = -832.47 kJ

(G( = -2.303RTlogK logK = (G( /-2.303(8.314E-3)(300+273.15)= -832.47/-10.975 = +75.85,

K = 10exp(+75.85) = 7.08 x 1075

(3) H2O(ℓ) ( H+ (aq) + OH-(aq) always nonspontaneous

(H( = (Hf(H+ (aq) + (Hf(OH-(aq) - (Hf(H2O(l) = 0 + (-230.0) –(-285.8) = 55.8kJ/mol rxn

q = [500g/(18)]mol x 55.8 = 1550 kJ

90( C: (G( = (H( -T (S( =55.8kJ/mol - 363(-0.0806) = 85.06 kJ

logK = (G( /-2.303(8.314E-3)(90+273.15)= 85.06/-2.303(8.314E-3)(363) = -12.24,

K = 10exp(-12.24) = 5.78 x 10-13

K = [H+][OH-] = [H+]2, [H+] = [pic] = 7.5 x 10-7, pH = 6.12

CHEM 1412 Sample Test 3

1. Calculate the molar solubility for each compound and compare

| |Ion ratio |Dissolution reaction |Ksp |S (molar solubi;ity) |

|a. AgCl |1/1 =1 |AgCl(s)( Ag+ + Cl- |1.8E-10 = S2 |1.34E-5 M |

|b. BaCO3 |1/1 = 1 |BaCO3 (s)( Ba2+ + CO32- |8.1E-9 = S2 |9.0E-5 M |

|c. Cd(OH)2(s) |2/1 = 2 |Cd(OH)2(s)( Cd2+ +2OH- |1.2E-14 = 4S3 |1.44E-5 |

Ans: b > c > a

2. a. qv = n(E -27.03 kJ = (1.000/44.05) (E (E = (-27.03)(44.05) = - 1190.8 kJ/mol rxn

b. C2H4O (g) + 5/2 O2(g) ( 2CO2(g) + 2H2O (ℓ) (n = 2 – 3.5 = -1.5

(Since the question asked about 1mol of ethanal, the coefficient for ethanal is fixed at one in

balanced equation, instead of using equation of minimal integral coefficients)

c. (H = (E + (nRT = - 1190.8 kJ/mol + (-1.5)(8.314E-3kJ/k.mol)(298.15K) = -1194.5 kJ/mol rxn

d. (H = 2 (Hfo, CO2(g) + 2 (Hfo, H2O(l) – ((Hfo,C2H4O(g) + 2.5(Hfo, O2(g) )

-1194.5 = 2 (-393.5) + 2(-285.8 ) -((Hfo,C2H4O(g) + 2.5 x 0 )

(Hfo,C2H4O(g) = +2 (-393.5) + 2(-285.8 ) –(-1194.5) = -164.1 kJ/mol

3. Mg(OH)2(s) ( Mg2+ +2OH-

At pH 3, high conc of H+ will neutralize OH-, make rxn (, increase the solubility

At pH 10, high conc of OH- will increase OH-, make rxn ( (CI effect), decrease the solubility

4. 2NO(g) + O2(g) ( 2NO2(g)

At 25(C, (G( < 0 (see following calculation), reaction is spontaneous

(G( = 2 (Gfo, NO2(g) - (2 (Gfo, NO(g) + (Gfo, O2(g) ) = 2 (51.30) – 2(86.57) = -70.54 kJ/mol rxn

(G( = -5.709 logK, -70.54 = -5.709 LogK logK = -70.54/-5.709 = 12.36,

K = 1012.36 = 2.29E12

(H( = 2 (Hfo, NO2(g) - (2 (Hfo, NO(g) + (Hfo, O2(g) ) = 2 (33.2) – 2(90.25) = -114.1 kJ/mol rxn

(S( = 2 So, NO2(g) - (2 So, NO(g) + So, O2(g) ) = 2 (240.0) – [2(210.7)+ 205.0] = -146.4 J/K.mol rxn

At 600(C, (G( > 0 (see following calculation), reaction is non-spontaneous

(G( = (H( - T(S( = -114.1 kJ/mol rxn – (600+273)(-0.1464 kJ/K.mol rxn) = 13.71 kJ/mol rxn

(G( = -2.303RTlogK 13.71 = -2.303(8.314E-3)(873)logK

logK = -0.82 K = 10-0.82 = 0.15

5. a. melting of ice : solid to liquid, entropy (

b. dissolving of NaCl in water: solid NaCl dissolved in liquid, entropy (

c. formation of H2O(ℓ) from H2(g) and O2(g): gas to liquid, entropy (

6. CH3OH(ℓ) ( CH3OH(g) ( Ho = +37.4kJ and (So = 111J/K

b.p. = ( Ho/(So = 37.4 kJ/0.111kJ/K = 336.9K = 63.8 (C

To calculate Keq at 25(C, use (G( = -5.709log K

(G( = (H( - T(S( = 37.4 kJ – (298K)(0.111kJ/K) = 4.32 kJ

(G( = -5.709log K 4.32 = -5.709logK logK = -0.757 K = 0.175

Based on (G(> 0, K < 1, evaporation is non-spontaneous. However, non-spontaneous

Is not the same as no reaction. It just means reaction is less likely to go forward than reverse

7. [Ans]: C6H12O6(s) + 6O2(g) ( 6CO2(g) + 6H2O(ℓ) (n = 6-6 = 0

qH2O = (SH)H2O(m)H2O(ΔT)H2O = (4.184kJ/kg oC.)(0.950kg)(3.15 oC)= 12.52 kJ

qcal = Ccal(ΔT)cal = Ccal(ΔT) H2O = (2.25 kJ/ oC)(3.15 oC) = 7.09 kJ

qrxn= qglucose = nglucose (ΔE) glucose = (1.25g/180.16) (ΔE) glucose

qtotal = qH2O + qcal + qrxn = 12.52 kJ + 7.09 kJ + qrxn

qrxn = -19.61 kJ = (0.00694 mol) (ΔE) ethanol (ΔE) ethanol = -2826 kJ/mol

Heat released is 19.61 kJ ( a positive term, since heat released implies exothermic)

(H = (E + (nRT = -2826 kJ/mol + (0)(8.314E-3)(298.15K)= -2826 kJ/mol)

When (n = 0, (H = (E

8. Given a. 2NF3(g) + 2NO(g) ( N2F4(g) + 2ONF(g) (H = -82.9kJ

b. NO(g) + 1/2 F2(g) ( ONF(g) (H = -156.9kJ

c. Cu(s) + F2(g) ( CuF2(s) (H = -530.1kJ

Target rxn: 2NF3(g) + Cu(s) ( N2F4(g) + CuF2(s), start from left to right

2NF3(g) need rxn (a): 2NF3(g) + 2NO(g) ( N2F4(g) + 2ONF(g) (Ha = -82.9kJ

Cu(s) need rxn (c): Cu(s) + F2(g) ( CuF2(s) (H = -530.1kJ

N2F4(g) needs rxn (a), but already used, skip to next

CuF2(s) needs rxn (c), but already used, stop to see what do we have now

Add rxns (a) and (c),

2NF3(g) + 2NO(g) + Cu(s) + F2(g) ( N2F4(g) + 2ONF(g) + CuF2(s)

(H = -82.9+ (-530.1) = -613 kJ

Compared with target rxn, there are extra terms (2NO, F2 and 2ONF) need to be eliminated

All the extra terms exist in rxn (b)

If subtract rxn (b)x2, we can get rid of all the terms:

2NF3(g) + 2NO(g) + Cu(s) + F2(g) ( N2F4(g) + 2ONF(g) + CuF2(s) (H = -613kJ

-2(b) 2NO(g) + F2(g) ( 2ONF(g) (H = (-156.9kJ)x2

Final 2NF3(g) + Cu(s) ( N2F4(g) + CuF2(s) (H = (-613) – (-156.9)x2 = -299.2 kJ

9. CH4 + 4 Cl2 ( CCl4 + 4 HCl

[pic]

(H = 4 C-H + 4 Cl-Cl – ( 4 C-Cl + 4 H-Cl) = 4 x 414 + 4 x 243 – (4 x 330 + 4 x 431) = -416 kJ

10. (H = (Hfo, CCl4(g) + 4 (Hfo, HCl(g) - ((Hfo, CH4(g) + 4 (Hfo, Cl2(g) )

= (-103) + 4 x (-92.31) – [(-74.81) + 4 x 0] = - 397.43 kJ/mol rxn

The value obtained by (Hfo ( -397.43 in this Q10) is more accurate than the one by bond energy

(-416 kJ in Q9). Because BE ‘s are given as average values and specifically for gaseous rxns.

11. a. Estimate the enthalpy of neutralization of 1.0 M HCl(aq) and 1.0 M NaOH(aq)

Based on complete molecular equation: HCl (aq) + NaOH(aq) ( NaCl(aq) + H2O (ℓ)

(H = (Hfo, NaCl(aq) + (Hfo, H2O(ℓ) - ((Hfo, HCl(aq) + 4 (Hfo, NaOH(aq) )

= (-407.1) + (-285.8) –[(-167.4) + (-469.6)] = -692.9 + 637 = - 55.9 kJ/mol rxn

Based on net ionic equation: H+(aq) + OH-(aq) ( H2O (ℓ)

(H = (Hfo, H2O(ℓ) - ((Hfo, H+(aq) + (Hfo, OH-(aq) ) = (-285.8) – (0 + (-230.0)) = -55.8 kJ/mol rxn

b. heat measured using coffee cup calorimeter(qp) or bomb calorimeter (qv) will be the same

qp = n(H qV = n(E (H = (E + (nRT

since (n = 0, (H = (E and qp = qV

c. the enthalpy of neutralization of 1.0 M HOAc(aq) and 1.0 M NaOH(aq) will be smaller compare to

the enthalpy of neutralization of 1.0 M HCl (aq) and 1.0 M NaOH(aq). HOAc is a WA, the

neutralization involves the breaking bond (endothermic, energy required) between H and

acetate; as a result less energy will be released.

HOAc (aq) + OH-(aq) ( H2O (ℓ) + OAc-(aq)

12. EDTA

[pic]

a. the four acidic H are those bonded to oxygen in the acetate groups

b. as shown in the Lewis structure, there are 10 atoms with lone paired electrons ( 2 N and

2 oxygens of each of the 4 acetate group)

c. the bond formation between EDTA and metal is an example of Lewis acid-base reaction

EDTA with many pairs of lone pair electron acts as Lewis base, donating electron pairs to

(sharing with) electron deficient metal (Lewis acid)

d. EDTA forms only 6 bonds with metal because the geometry (space limitation) such that only

one oxygen from each acetate group can bond to metal

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