Chemistry: An Atoms First Approach
Chemistry: An Atoms First Approach
2nd Edition
ISBN: 9781305079243
Author: Steven S. Zumdahl, Susan A. Zumdahl
Publisher: Cengage Learning
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Chapter 16, Problem 122MP

Impure nickel, refined by smelting sulfide ores in a blast furnace, can be converted into metal from 99.90% to 99.99% purity by the Mond process. The primary reaction involved in the Mond process is

Ni ( s ) + 4CO ( g ) Ni ( CO ) 4 ( g )

a. Without referring to Appendix 4, predict the sign of ∆S° for the above reaction. Explain.

b. The spontaneity of the above reaction is temperature-dependent. Predict the sign of ∆Ssurr, for this reaction. Explain

c. For Ni(CO)4(g), Δ H f o = 607 KJ/mol and S° = 417 J/K ·mol at 298 K. Using these values and data in Appendix 4, calculate ∆H° and ∆S° for the above reaction.

d. Calculate the temperature at which ∆G° = 0 (K = 1) for the above reaction, assuming that ∆H° and ∆S° do not depend on temperature.

e. The first step of the Mood process involves equilibrating impure nickel with CO(g) and Ni(CO)4(g) at about 50°C. The purpose of this step is to convert as much nickel as possible into the gas phase. Calculate the equilibrium constant for the above reaction at 50.°C.

f. In the second step of the Mood process, the gaseous Ni(CO)4 is isolated and heated to 227°C. The purpose of this step is to deposit as much nickel as possible as pure solid (the reverse of the preceding reaction). Calculate the equilibrium constant for the preceding reaction at 227°C.

g. Why is temperature increased for the second step of the Mood process?

h. The Mond process relies on the volatility of Ni(CO)4 for its success. Only pressures and temperatures at which Ni(CO)4 is a gas are useful. A recently developed variation of the Mood process carries out the first step at higher pressures and a temperature of l52°C. Estimate the maximum pressure of Ni(CO)4(g) that can be attained before the gas will liquefy at 152°C. The boiling point for Ni(CO)4 is 42°C and the enthalpy of vaporization is 29.0 kJ/mol.

[Hint: The phase change reaction and the corresponding equilibrium expression are

Ni ( CO ) 4 ( l ) Ni ( CO ) 4 ( g ) K = P Ni ( CO ) 4

Ni(CO)4(g) will liquefy when the pressure of Ni(CO)4 is greater than the K value.]

 (a)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The given questions based upon Mond process are to be answered.

Concept introduction: The Mond process relies on the volatility of Ni(CO)4 for its success. The temperatures and pressures at which Ni(CO)4 is gas are useful.

To determine: The sign of ΔSο for the reaction.

Answer to Problem 122MP

The sign of ΔSο for the reaction is negative.

Explanation of Solution

The given reaction is,

Ni(s)+4CO(g)Ni(Co)4(g)

There are four gaseous molecules present on the reactant side and one gaseous molecule present at the product side. Since the number of gaseous molecules decreases in the reaction, hence the standard entropy change ΔSο for the reaction becomes negative.

(b)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The given questions based upon Mond process are to be answered.

Concept introduction: The Mond process relies on the volatility of Ni(CO)4 for its success. The temperatures and pressures at which Ni(CO)4 is gas are useful.

To determine: The sign of ΔSsurr for the reaction.

Answer to Problem 122MP

The sign of ΔSsurr for the reaction is positive.

Explanation of Solution

Since the entropy for the system is decreasing, therefore the sign of ΔSsurr should be positive so that the entropy of universe always increases.

(c)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The given questions based upon Mond process are to be answered.

Concept introduction: The Mond process relies on the volatility of Ni(CO)4 for its success. The temperatures and pressures at which Ni(CO)4 is gas are useful.

To determine: The value of ΔHο and ΔSο for the reaction.

Answer to Problem 122MP

The value of ΔHο is -565 kJ/mol_ and the value of ΔSο is -405J/mol_ .

Explanation of Solution

The given reaction is,

Ni(s)+4CO(g)Ni(Co)4(g)

The standard enthalpy change ( ΔHο ) is calculated by the formula,

ΔHο=(Number of moles of products×ΔHfοProducts Number of moles of reactants×ΔHfοReactants)

ΔHο=(Number of moles of Ni(Co)4(g)×ΔHfοNi(Co)4(g) (Number of moles of Ni(s)×ΔHfοNi(s)+Number of moles ofCO(g)×ΔHfοCO(g)))

The number of moles of Ni(Co)4(g) is 1 .

The number of moles of Ni(s) is 1 .

The number of moles of CO(g) is 4 .

ΔHfοNi(Co)4(g) =Standard enthalpy of formation of Ni(Co)4(g) = -607kJ/mol .

ΔHfοNi(s) =Standard enthalpy of formation of Ni(s)=0

ΔHfοCO(g) = Standard enthalpy of formation of CO(g)=-10.5kJ/mol

Substitute the number of moles of reactants and products and their standard enthalpy of formation in the above equation.

ΔHο=((1×607 kJ/mol) (1×0+4×10.5 kJ/mol))=-565 kJ/mol_

The conversion of kJ/mol to J/mol is done as,

1 kJ/mol=103 J/mol

Therefore, the conversion of -565 kJ/mol to J/mol is done as,

-565 kJ/mol=565×103 J/mol

Therefore, the value of standard enthalpy change ( ΔHο ) is 565×103 J/mol .

The standard entropy change ( ΔSο ) is calculated by the formula,

ΔSο=(Number of moles of products×SοProducts Number of moles of reactants×SοReactants)

ΔSο=(Number of moles of Ni(Co)4(g)×SοNi(Co)4(g) (Number of moles of Ni(s)×SοNi(s)+Number of moles ofCO(g)×SοCO(g)))

The number of moles of Ni(Co)4(g) is 1 .

The number of moles of Ni(s) is 1 .

The number of moles of CO(g) is 4 .

SοNi(Co)4(g) =Standard entropy of Ni(Co)4(g) = 417J/Kmol .

SοNi(s) =Standard entropy of Ni(s)=30J/Kmol

SοCO(g) = Standard entropy of CO(g)=198J/Kmol

Substitute the number of moles of reactants and products and their standard entropy in the above equation.

ΔSο=((1mol×417 J/Kmol) (1mol×30 J/Kmol+4mol×198J/Kmol))=-405J/K_

(d)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The given questions based upon Mond process are to be answered.

Concept introduction: The Mond process relies on the volatility of Ni(CO)4 for its success. The temperatures and pressures at which Ni(CO)4 is gas are useful.

To determine: The temperature at which ΔGο for the reaction is zero.

Answer to Problem 122MP

The temperature at which ΔGο=0 is 1395K_ .

Explanation of Solution

The standard free energy change formula is,

ΔGο=ΔHοTΔSο

It is given that ΔGο=0 . Therefore, the equation becomes,

T=ΔHοΔSο

Substitute the value of ΔHο and ΔSο in the above equation.

T=565×103 J/mol-405J/K=1395K_

(e)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The given questions based upon Mond process are to be answered.

Concept introduction: The Mond process relies on the volatility of Ni(CO)4 for its success. The temperatures and pressures at which Ni(CO)4 is gas are useful.

To determine: The equilibrium constant for the reaction at 50οC .

Answer to Problem 122MP

The equilibrium constant for the reaction at 50οC is 1.95×1070_ .

Explanation of Solution

The standard free energy change formula is,

ΔGο=ΔHοTΔSο

The temperature ( T ) is 50οC=323K .

The value of ΔHο is -565kJ .

The value of ΔSο is -405J/K .

Substitute the value of T , ΔHο and ΔSο in the above equation.

ΔGο=565kJ323K×405J/K=565kJ+131×103J=565kJ+131kJ=434kJ

The conversion of kJ/mol to J/mol is done as,

1 kJ/mol=103 J/mol

Therefore, the conversion of 434kJ to J/mol is done as,

434kJ=434×103 J/mol

Therefore, the value of standard free energy change ( ΔGο ) is 434×103 J/mol .

Since,

ΔG=ΔGο+RTlnQ .

Where,

  • ΔG is the change in gibbs free energy.
  • Q is the reaction quotient.
  • K is the equilibrium constant.
  • R is the gas constant ( 8.3145J/Kmol ).

At equilibrium, ΔG=0 and Q=K .

Substitute the value of ΔG and Q in the above equation.

ΔGο=RTlnKlnK=ΔGοRT

Substitute the value of ΔGο , R and T in the above equation.

lnK=434×103 J/mol8.3145J/Kmol×323KlogK=1622.303logK=70.3K=1.95×1070

Thus, the value of equilibrium constant for the reaction is 1.95×1070_ .

(f)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The given questions based upon Mond process are to be answered.

Concept introduction: The Mond process relies on the volatility of Ni(CO)4 for its success. The temperatures and pressures at which Ni(CO)4 is gas are useful.

To determine: The equilibrium constant for the reaction at 227οC .

Answer to Problem 122MP

The equilibrium constant for the reaction at 227οC is 7.94×1037_ .

Explanation of Solution

The standard free energy change formula is,

ΔGο=ΔHοTΔSο

The temperature ( T ) is 227οC=500K .

The value of ΔHο is -565kJ .

The value of ΔSο is -405J/K .

Substitute the value of T , ΔHο and ΔSο in the above equation.

ΔGο=565kJ500K×405J/K=565kJ+202×103J=565kJ+204.5kJ=363kJ

The conversion of kJ/mol to J/mol is done as,

1 kJ/mol=103 J/mol

Therefore, the conversion of 363kJ to J/mol is done as,

363kJ=363×103 J/mol

Therefore, the value of standard free energy change ( ΔGο ) is 363×103 J/mol .

Since,

ΔG=ΔGο+RTlnQ .

Where,

  • ΔG is the change in gibbs free energy.
  • Q is the reaction quotient.
  • K is the equilibrium constant.
  • R is the gas constant ( 8.3145J/Kmol ).

At equilibrium, ΔG=0 and Q=K .

Substitute the value of ΔG and Q in the above equation.

ΔGο=RTlnKlnK=ΔGοRT

Substitute the value of ΔGο , R and T in the above equation.

lnK=363×103 J/mol8.3145J/Kmol×500KlogK=87.22.303logK=37.9K=7.94×1037

Thus, the value of equilibrium constant for the reaction is 7.94×1037_ .

(g)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The given questions based upon Mond process are to be answered.

Concept introduction: The Mond process relies on the volatility of Ni(CO)4 for its success. The temperatures and pressures at which Ni(CO)4 is gas are useful.

To determine: The reason for increase in temperature in second step.

Answer to Problem 122MP

The purpose of increase in temperature is to enhance the yield of pure nickel.

Explanation of Solution

In the second step of Mond process, the temperature is increased. By doing this, the equilibrium will shift in reverse direction. Hence, deposition of as much as nickel as pure solid will take place.

(h)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: The given questions based upon Mond process are to be answered.

Concept introduction: The Mond process relies on the volatility of Ni(CO)4 for its success. The temperatures and pressures at which Ni(CO)4 is gas are useful.

To determine: The maximum pressure of NiCO4(g) that can be attained before the gas liquefy at 152οC .

Answer to Problem 122MP

The maximum pressure of NiCO4(g) that can be attained before the gas will liquefy at 152οC is 3.38×1040 .

Explanation of Solution

The standard free energy change formula is,

ΔGο=ΔHοTΔSο

The temperature ( T ) is 152οC=425K .

The value of ΔHο is -565kJ .

The value of ΔSο is -405J/K .

Substitute the value of T , ΔHο and ΔSο in the above equation.

ΔGο=565kJ425K×405J/K=565kJ+172.1×103J=565kJ+172.1kJ=392.9kJ

The conversion of kJ/mol to J/mol is done as,

1 kJ/mol=103 J/mol

Therefore, the conversion of 392.9kJ to J/mol is done as,

392.9kJ=392.9×103 J/mol

Therefore, the value of standard free energy change ( ΔGο ) is 392.9×103 J/mol .

Since,

ΔG=ΔGο+RTlnQ .

Where,

  • ΔG is the change in Gibbs free energy.
  • Q is the reaction quotient.
  • K is the equilibrium constant.
  • R is the gas constant ( 8.3145J/Kmol ).

At equilibrium, ΔG=0 and Q=K .

Substitute the value of ΔG and Q in the above equation.

ΔGο=RTlnKlnK=ΔGοRT

Substitute the value of ΔGο , R and T in the above equation.

lnK=392.9×103 J/mol8.3145J/Kmol×425KlogK=93.352.303logK=40.53K=3.38×1040

Thus, the value of equilibrium constant for the reaction is 3.38×1040 .

The phase change reaction and the corresponding equilibrium expression is,

NiCO4(l)NiCO4(g)

The equilibrium constant ( K ) expression for the above reaction is,

K=PNi(CO)4

Where,

  • PNi(CO)4 is the pressure of NiCO4(g) .

Substitute the value of K in the above equation.

PNi(CO)4=3.38×1040

The NiCO4(g) will liquefy when pressure of NiCO4(g) is greater than K value. Therefore, the maximum pressure of NiCO4(g) that can be attained before the gas will liquefy at 152οC is 3.38×1040

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Chapter 16 Solutions

Chemistry: An Atoms First Approach

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