Physical Chemistry
Physical Chemistry
2nd Edition
ISBN: 9781285969770
Author: Ball
Publisher: Cengage
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Chapter 8, Problem 8.15E
Interpretation Introduction

Interpretation:

The reaction that can provide sufficient energy to do required work is to be identified.

Concept Introduction:

Standard Gibbs free energy of a reaction is used check whether the reaction is spontaneous or not. If the value of ΔG° is positive, then the reaction is non spontaneous. If the value of ΔG° is negative, then the reaction is spontaneous. Standard Gibbs free energy of a redox reaction is also represented as the maximum amount of work done by the system on the surrounding.

Expert Solution & Answer
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Answer to Problem 8.15E

Correct answer:

The correct option is (b) and (d).

Explanation of Solution

Reason for correct answer:

(b)

The given chemical equation (b) is represented as,

Fe+Ag+Fe3++Ag

From Table 8.2, the reduction half reaction of Fe2+ and the standard reduction potential of Fe2+ is represented as,

Fe3++3eFe     E°=0.037V

The number of moles of electrons transferred in the above reaction is 3mol.

The above equation is reversed and the value of E° is multiplied by 1., to form an oxidation half reaction. The oxidation half reaction is represented as,

FeFe3++3e     E°=0.037V …(1)

From Table 8.2, the reduction half reaction of Ag+ and the standard reduction potential of H+ is represented as,

Ag++eAg     E°=0.7996V …(2)

The number of moles of electrons transfer in the above reaction is 1mol.

The relation between standard Gibbs free energy and standard electrical potential is represented as,

ΔG°=nFE° …(3)

Where,

ΔG° represents the standard Gibbs free energy of the reaction.

N represents the number of moles.

F represents the Faraday’s constant with value 96,485 C/mol.

E° represents the standard electrical potential.

Substitute the values of the standard oxidation potential of Fe, F and number of moles of electrons transferred in the equation (3).

ΔG°=(3 mol)(96,485 C/mol)(0.037V)(1J/C1 V)=(10709.835J)(1 kJ1000 J)=10.7098 kJ

The value ΔG° for the reaction (1) is 10.7098 kJ.

Substitute the values of the standard reduction potential of Ag+, F and number of moles of electrons transfer in the equation (3).

ΔG°=(1 mol)(96,485 C/mol)(0.7996V)(1J/C1 V)=(77149.409J)(1 kJ1000 J)=77.1494 kJ

The value ΔG° for the reaction (2) is 77.1494 kJ.

The balanced overall electrochemical reaction is obtained when chemical equation (2) is multiplied by 3 and is added in chemical equation (1). The formation of overall balanced chemical equation is represented as,

FeFe3++3e                     ΔG°=10.7098 kJ3Ag++3e3Ag            3×ΔG°=3×(77.1494 kJ)Fe+3Ag+Fe3++3Ag       ΔG°=242.158kJ

Therefore, the value ΔG° for the given reaction is 242.158kJ.

The maximum amount of work that can be done by the given chemical reaction (b) is 242.158kJ.

(d)

The given chemical equation (d) is represented as,

Au++ZnAu+Zn2+

From Table 8.2, the reduction half reaction of Zn2+ and the standard reduction potential of Zn2+ is represented as,

Zn2++2eZn      E°=0.7618V

The above equation is reversed and the value of E° is multiplied by 1, to from an oxidation half reaction. The oxidation half reaction is represented as,

ZnZn2++2e      E°=0.7618V …(4)

The number of moles of electrons transfer in the above reaction is 2mol.

From Table 8.2, the reduction half reaction of Au+ and the standard reduction potential of Au is represented as,

Au++eAu      E°=1.692V …(5)

The number of moles of electrons transfer in the above reaction is 1mol.

Substitute the values of the standard oxidation potential of Zn, F and number of moles of electrons transfer in the equation (3).

ΔG°=(2 mol)(96,485 C/mol)(0.7618V)(1J/C1 V)=(147004.546J)(1 kJ1000 J)=147.004kJ

The value ΔG° for the reaction (4) is 147.004kJ.

Substitute the values of the standard reduction potential of Au, F and n in the equation (3).

ΔrxnG°=(1 mol)(96,485 C/mol)(1.692V)(1J/C1 V)=(163242.62J)(1 kJ1000 J)=163.24kJ

The value ΔG° for the reaction (5) is 163.24kJ.

The balanced overall electrochemical reaction is obtained when chemical equation (5) is multiplied by 2 and then added in chemical equation (4). The formation of overall balanced chemical equation is represented as,

ZnZn2++2e                    ΔG°=147.004kJ2Au++2e2Au            2×ΔG°=2×(163.24kJ)2Au++Zn2Au+Zn2+     ΔG°=473.484kJ

Therefore, the value ΔG° for the given reaction (d) is 473.484kJ.

The required work done is 196kJ.

Therefore, the given reaction (b) and (d) can provide enough energy to perform the process.

The correct options are (b) and (d).

Reason for incorrect options:

(a)

The given chemical equation (a) is represented as,

Cu2++H2Cu+H+

From Table 8.2, the reduction half reaction of Cu2+ and the standard reduction potential of Cu+ is represented as,

Cu2++2eCu     E°=0.3419V …(6)

The number of moles of electrons transfer in the above reaction is 2mol.

From Table 8.2, the reduction half reaction of H+ and the standard reduction potential of H+ is represented as,

2H++2eH2     E°=0V

The number of moles of electrons transfer in the above reaction is 2mol.

The above equation is reversed and the value of E° is multiplied by 1, to from an oxidation half reaction. The oxidation half reaction is represented as,

H22H++2e     E°=0V …(7)

Substitute the values of the standard reduction potential of Cu2+, F and number of moles of electrons transfer in the equation (3).

ΔG°=(2 mol)(96,485 C/mol)(0.3419V)(1J/C1 V)=(65976.443J)(1 kJ1000 J)=65.9764kJ

The value ΔG° for the reaction (6) is 65.9764kJ.

The standard electrical potential of the reaction (7) is 0.0V. Therefore, the value ΔG° for the reaction (7) is 0 kJ.

The balanced overall electrochemical reaction is obtained when chemical equation (6) is added in chemical equation (7). The formation of overall balanced chemical equation is represented as,

Cu2++2eCu                   ΔG°=65.9764kJH22H++2e                   ΔG°=0kJCu2++H2Cu+2H+       ΔG°=65.9764kJ

Therefore, the value ΔG° for the given reaction (a) is 65.9764kJ.

(c)

The given chemical equation (c) is represented as,

Co+Ni2+Co2++Ni

From Table 8.2, the reduction half reaction of Co2+ and the standard reduction potential of Co2+ is represented as,

Co2++2eCo      E°=0.28V

The above equation is reversed and the value of E° is multiplied by 1, to from an oxidation half reaction. The oxidation half reaction is represented as,

CoCo2++2e      E°=+0.28V …(8)

The chemical equation (7) is reversed and the value of E° is multiplied by 1, to from an oxidation half reaction. The oxidation half reaction is represented as,

Ni2++2eNi    E°=0.257V …(9)

The number of moles of electrons transfer in the above reaction is 2mol.

Substitute the values of the standard oxidation potential of Co, F and number of moles of electrons transfer in the equation (3).

ΔG°=(2 mol)(96,485 C/mol)(0.28V)(1J/C1 V)=(154376J)(1 kJ1000 J)=154.376 kJ

The value ΔG° for the reaction (8) is 154.376 kJ.

Substitute the values of the standard reduction potential of Ni2+, F and number of moles of electrons transfer in the equation (3).

ΔG°=(2 mol)(96,485 C/mol)(0.257V)(1J/C1 V)=(49593.29J)(1 kJ1000 J)=49.5933kJ

The value ΔG° for the reaction (9) is 49.5933kJ.

The balanced overall electrochemical reaction is obtained when chemical equation (8) is added in chemical equation (9). The formation of overall balanced chemical equation is represented as,

CoCo2++2e             ΔG°=154.376 kJNi2++2eNi               ΔG°=49.5933kJCo+Ni2+Co2++Ni    ΔG°=104.7827kJ

The value ΔG° for the given reaction (c) is 104.7827kJ.

The energy produce by the reaction (a) and (b) is less than the required energy.

Therefore, the option (a) and (c) are incorrect.

Conclusion

The reaction (b) and reaction (d) provides sufficient amount of energy to do required work. Therefore, the option (b) and (d) are correct.

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