Chemistry
Chemistry
4th Edition
ISBN: 9780078021527
Author: Julia Burdge
Publisher: McGraw-Hill Education
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Chapter 19, Problem 24QP

Calculate G ° and K c for the following reactions at 25 ° C:

( a ) Mg ( s ) + p b 2 + ( a q ) Mg 2+ ( a q ) + p b ( s )

( b ) O 2 ( g ) + 4 H + ( a q ) + 4 F e 2 + ( a q ) 2 H 2 O ( I ) + 4 F e 3 + ( a q )

( c ) 2 A 1 ( s ) + 31 2 ( s ) 2 A 1 3 + ( a q ) + 61 ( a q )

Expert Solution & Answer
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Interpretation Introduction

Interpretation:

The equilibrium constant (K) and the Gibbs free energy (ΔGo) for each of the given chemical reactions areto be calculated.

Concept introduction:

The standard cell potential of a particular cell is given as:

E0cell = E0cathodeE0anode

Here, E0cathodeand  E0anode is the standard reduction potential occurring at the cathode and anode, respectively.

The relation between the cell potential (E0cell) and the equilibrium constant (K) is given as:

E0cell = 0.0592n×logK

The relation between standard Gibbs free energy (ΔGo) and the standard cell potential (E0cell) is given as:

ΔG0=nFEocell

Answer to Problem 24QP

Solution:

(a) ΔGo=432 kJ/mol and  K = 5×1075

(b) ΔGo=178 kJ/mol and  K=1×1031

(c) ΔGo=1.27 × 103 kJ/mol and  K = 9×10221

Explanation of Solution

a) Mg(s) + Pb2+(aqMg2+(aq) + Pb (s

This reaction can be written astwo half-reactions, as follows:

At cathode (reduction):Pb2+(aq)+2ePb(s)

At anode(oxidation):Mg (s Mg2+(aq)+2e

Fromtable 19.1, the reduction potential of lead is 0.13 V and the reduction potential of magnesium is 2.37 V.

Now, the standard cell potential of the cell is given as:

E0cell=E0cathodeE0anode

Substitute the values of half-cell potential in the above expression.

Eocell=(0.13 V (2.37 V))           = 2.24 V

The relation between standard Gibbs free energy (ΔGo) and the standard cell potential (E0cell) is as follows:

ΔGo=nFEocell

Here, the number of exchange of electrons is two;

Thus, the value of n = 2.

Substitute the values of Faraday constant, the number of electrons transferred in the half-cell and the standard cell potential.

ΔGo=(2×96500 JV.mol× 2.24 V)        =432320 J/mol        =432 kJ/mol

The relation between the cell potential (E0cell) and the equilibrium constant (K) is given as follows:

E0cell = 0.0592n×logK K = 10nEocell0.0592V

Substitute the values n and E0cell to the above expression,

K = 102× 2.24 V0.0592K = 1075.7K= 5 × 1075

Thus, the equilibrium constant of this reaction is × 1075.

b) O2(g)+4H+(aq)+4Fe2+(aq)2H2O(l)+4Fe3+(aq

This reaction can be written astwo half-reactions, as follows:

At cathode (reduction):O2(g) + 4H+(aq) + 4e2H2(l)

At anode(oxidation):4Fe2+(aq) 4Fe3+(aq) + 4e

Fromtable 19.1, the reduction potential of oxygen gas is 1.23 V and the reduction potential of iron is 0.77 V.

The standard cell potential of a cell is given as follows:

E0cell=E0cathodeE0anode

Substitute the values of half-cell potential in the above expression:

Eocell=1.23 V 0.77 V           = 0.46 V

The relation between standard Gibbs free energy (ΔGo) and the standard cell potential (E0cell) is given as:

ΔG0=nFEocell

Here, the number of exchange of electrons is four;

Thus, the value of n = 4.

The Gibb’s energy is calculated by the expression as follows:

ΔGo =(4×96500 JV.mol× 0.46 V)        = 177560 J/mol        = 178 kJ/mol

The relation between the cell potential (E0cell) and the equilibrium constant (K) is given as follows:

E0cell = 0.0592n×logK K = 10nEocell0.0592V

Substitute the values of n and Ecell0 in the above expression,

=104× 0.46 V0.0592=1031.1K=× 1031

Thus, the equilibrium constant of this reaction is × 1031.

c) 2Al(s)+3I2(s2Al3+(aq)+6I(aq

This reaction can be written astwo half-reactions as follows:

At cathode (reduction):3I2(s) + 6e6I(aq)

At anode(oxidation):2Al (s 2Al3+(aq) + 6e

Fromtable 19.1, the reduction potential of aluminum is 1.66 V and the reduction potential of iodine is 0.53 V.

The standard cell potential of a cell is given as follows:

E0cell=E0cathode E0anode

Substitute the values of half-cell potential in the above expression,

Eocell = 0.53 V - (-1.66 V)           = 2.19 V

The relation between standard Gibbs free energy (ΔGo) and the standard cell potential (E0cell) is given as follows:

ΔG0=nFEocell

Here, number of exchange of electrons is six;

Thus, the value of n = 6.

Substitute the values of n and Ecell0 in the above expression.

ΔGo =(6×96500 JV.mol× 2.19 V)        =1268010 J/mol        =1.27 × 103 kJ/mol

The relation between the cell potential (E0cell) and the equilibrium constant (K) is given as follows:

E0cell=(0.0592n×logK)K=10nEocell0.0592V

Substitute the values of n and Ecell0 in the above expression,

K=106× 2.19 V0.0592K=10221.96K=× 10221

Thus, the equilibrium constant of this reaction is × 10221.

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Chapter 19 Solutions

Chemistry

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