Physical Chemistry
Physical Chemistry
2nd Edition
ISBN: 9781133958437
Author: Ball, David W. (david Warren), BAER, Tomas
Publisher: Wadsworth Cengage Learning,
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Chapter 4, Problem 4.60E
Interpretation Introduction

(a)

Interpretation:

The value of change in pressure required to get a value of ΔG equal to +1.000kJ is to be calculated.

Concept introduction:

The Gibbs free energy of the system represents the maximum amount of non-expansion work achieved by a thermodynamic system at isothermal and isobaric conditions. The change in Gibbs free energy is used to predict the spontaneity of the process. The change in Gibbs energy of the condensed system is represented as shown below.

ΔG=VΔp

Expert Solution
Check Mark

Answer to Problem 4.60E

The value of change in pressure required to get a value of ΔG equal to +1.000kJ is 547.7092atm.

Explanation of Solution

The number of moles of water is 1.00mol.

The molar volume is 18.02cm3 which means that the volume of one mole of water is 18.02cm3.

The required value ΔG is +1.000kJ.

The change in Gibbs energy of the condensed system is represented as shown below.

ΔG=VΔp…(1)

Where,

V represents the volume of the system.

Δp represents the change in pressure of the system.

Rearrange the equation (1) for the value of Δp.

Δp=ΔGV…(2)

Substitute the value of V and ΔG in the equation (2).

Δp=(+1.000kJ18.02cm3)(1000cm31L)(1000J1kJ)(1Latm101.32J)=547.7092atm

Therefore, the value of change in pressure required to get a value of ΔG equal to +1.000kJ is 547.7092atm.

Conclusion

The value of change in pressure required to get a value ΔG equal to +1.000kJ is 547.7092atm.

Interpretation Introduction

(b)

Interpretation:

The value of change in pressure for 1mol of ideal gas at 25°C required to get a value ΔG equal to +1.000kJ is to be calculated.

Concept introduction:

The Gibbs free energy of the system represents the maximum amount of non-expansion work achieved by a thermodynamic system at isothermal and isobaric conditions. The change in Gibbs free energy is used to predict the spontaneity of the process. The change in Gibbs energy of the gaseous system isrepresented as shown below.

ΔG=nRTlnpfpi

Expert Solution
Check Mark

Answer to Problem 4.60E

The value of change in pressure for 1mol of ideal gas at 25°C required to get a value ΔG equal to +1.000kJ is 0.4972atm.

Explanation of Solution

The temperature of the ideal gas is 25°C.

The temperature of the ideal gas in Kelvin is calculated as shown below.

T=(273+25.0°C)K=298K

The required value of ΔG is +1.000kJ.

The number of moles of the ideal gas is 1.00mol.

The change in Gibbs energy of the gaseous system is represented as shown below.

ΔG=nRTlnpfpi…(3)

Where,

pf represents the final pressure of the ideal gas.

pi represents the initial pressure of the ideal gas.

n represents the number of moles of the ideal gas.

T represents the temperature of the ideal gas.

R represents the ideal gas constant with value 8.314J/Kmol.

Rearrange the equation (3) for the value of lnpfpi.

lnpfpi=ΔGnRT

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

lnpfpi=(+1.000kJ)(1000J1kJ)(1.00mol)(298K)(8.314J/Kmol)lnpfpi=0.4036

The above expression is further solved as shown below.

exp(lnpfpi)=exp(0.4036)pfpi=1.4972

One is subtracted from both sides of the above expression.

pfpi1=1.49721pfpipi=0.4972Δppi=0.4972

When the initial pressure of an ideal gas is assumed to be 1atm, the above expression becomes as follows.

Δp1atm=0.4972Δp=0.4972atm

Therefore, the value of change in pressure for 1mol of ideal gas at 25°C required to get a value of ΔG equal to +1.000kJ is 0.4972atm.

Conclusion

The value of change in pressure for 1mol of ideal gas at 25°C required to get a value ΔG equal to +1.000kJ is 0.4972atm.

Interpretation Introduction

(c)

Interpretation:

The difference between the two corresponding values of change in pressure is to be explained.

Concept introduction:

The Gibbs free energy of the system represents the maximum amount of non-expansion work achieved by a thermodynamic system at isothermal and isobaric conditions. The change in Gibbs free energy is used to predict the spontaneity of the process. The change in Gibbs energy of the gaseous system isrepresented as shown below.

ΔG=nRTlnpfpi

Expert Solution
Check Mark

Answer to Problem 4.60E

The value of change in pressure for 1mol of ideal gas at 25°C required to obtain a value of ΔG equal to +1.000kJ is higher in case of water.

Explanation of Solution

The value of change in pressure for 1mol of ideal gas at 25°C required to get a value of ΔG equal to +1.000kJ is 0.4972atm.

The value of change in pressure for 1mol of water required to get a value ΔG equal to +1.000kJ is 547.7092atm.

The value of change in pressure for 1mol of ideal gas at 25°C required to get a value ΔG equal to +1.000kJ is higher in case of water.

The gases are easily compressible than a condensed phase system. A small increase in pressure is required for compression of gas and a large increase in pressure is required to compress water. Therefore, the compression of gas requires less pressure than the compression of water.

Conclusion

The value of change in pressure for 1mol of ideal gas at 25°C required to get a value ΔG equal to +1.000kJ higher in case of water. The reason for this difference is that compression of gas requires less pressure than compression of water.

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