Thermodynamics: An Engineering Approach
Thermodynamics: An Engineering Approach
9th Edition
ISBN: 9781259822674
Author: Yunus A. Cengel Dr., Michael A. Boles
Publisher: McGraw-Hill Education
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Chapter 16.6, Problem 27P

(a)

To determine

The equilibrium constant obtained from the equilibrium reaction at 298 K.

(a)

Expert Solution
Check Mark

Answer to Problem 27P

The equilibrium constant obtained from the equilibrium reaction at 298 K is 8.24×1046.

Explanation of Solution

Express the standard-state Gibbs function change.

ΔG*(T)=vCOg¯*CO(T)+vO2g¯*O2(T)vCO2g¯*CO2(T)                                                         (I)

Here, the Gibbs function of components CO,O2,andCO2 at 1 atm pressure and temperature T are g¯*CO(T),g¯*O2(T),andg¯*CO2(T) respectively and stoichiometric coefficients of components CO,O2,andCO2 are vCO,vO2,andvCO2 respectively.

Write the equation to calculate the natural logarithms of equilibrium constant for the chemical equilibrium of ideal-gas mixtures.

lnKP=ΔG*(T)RuT (II)

Here, universal gas constant is Ru and temperature of Gibbs function of formation is T.

Write the equation to calculate the equilibrium constant for the chemical equilibrium of ideal-gas mixtures.

KP=e(ΔG*(T)RuT) (III)

Conclusion:

From the equilibrium reaction, the values of vCO,vO2,andvCO2 are 1, 0.5, and 1 respectively.

Refer to Table A-26; obtain the values of g¯*CO, g¯*O2,andg¯*CO2 as below:

g¯*CO=137150 kJ/kmolg¯*O2=0kJ/kmol g¯*CO2=394360kJ/kmol

Substitute 1 for vCO, 1 for vCO2, 0.5 for vO2, 137150 kJ/kmol for g¯*CO, 0kJ/kmol for g¯*O2, and 394360kJ/kmol for g¯*CO2 in equation (I).

ΔG*(T)=1(137150 kJ/kmol)+0.5(0)1(394360kJ/kmol)=257210 kJ/kmol

Substitute 257210 kJ/kmol for ΔG*(T), 25°C for T, and 8.314kJ/kmolK for Ru in Equation (II).

lnKP=257210 kJ/kmol(8.314kJ/kmolK)×298 K=103.81

Substitute 103.81 for KP in Equation (III).

KP=e(103.81)=8.24×1046

Thus, the equilibrium constant obtained from the equilibrium reaction at 298 K is 8.24×1046.

The value obtained for equilibrium constant at 298 K from the definition of the equilibrium constant is 103.81 which is equal to the value obtained for equilibrium constant as 103.76 from Table A-28.

(b)

To determine

The equilibrium constant obtained from the equilibrium reaction at 1800K.

(b)

Expert Solution
Check Mark

Answer to Problem 27P

The equilibrium constant obtained from the equilibrium reaction at 1800Kis 2.03×104.

Explanation of Solution

Write the expression to obtain standard-state Gibbs function change.

ΔG*(T)=vCOg¯*CO(T)+vO2g¯*O2(T)vCO2g¯*CO2(T)=vCO(h¯Ts¯)CO+vO2(h¯Ts¯)O2vCO2(h¯Ts¯)CO2=[vCO(h¯fo,CO+(h¯COh¯oCO)Ts¯CO)+vO2(h¯f,O2o+(h¯O2h¯oO2)Ts¯O2)vCO2(h¯fo,CO2+(h¯CO2h¯oCO2)Ts¯CO2)] (IV)

Here, the Gibbs function of components CO,O2,andCO2 at 1 atm pressure and temperature T are g¯*CO(T),g¯*O2(T),andg¯*CO2(T) respectively, enthalpy on the unit mole basis of CO,O2,andCO2 are h¯CO,h¯O2,andh¯CO2 respectively, absolute entropy of CO,O2,andCO2 are s¯CO,s¯O2,ands¯CO2, the sensible enthalpy at the standard reference state of 298 K and 1 atm of CO,O2,andCO2 are h¯COo,h¯O2o,andh¯CO2o, the enthalpy of formation at a specified states of 298 K and 1 atm for the components CO,O2,andCO2 are h¯f,COo,h¯f,O2o,andh¯f,CO2o, stoichiometric coefficients of components CO,O2,andCO2 are vCO,vO2,andvCO2 respectively.

Write the equation to calculate the natural logarithms of equilibrium constant for the chemical equilibrium of ideal-gas mixtures.

lnKP=ΔG*(T)RuT (V)

Here, universal gas constant is Ru and temperature of Gibbs function of formation is T.

Write the equation to calculate the equilibrium constant for the chemical equilibrium of ideal-gas mixtures.

KP=e(ΔG*(T)RuT) (VI)

Conclusion:

From the equilibrium reaction, the values of vCO,vO2,andvCO2 are 1, 0.5 and 1 respectively.

Refer Table A-26, obtain the values of h¯f,COo,h¯f,O2o,andh¯f,CO2o as below:

h¯f,COo=110530kJ/kmolh¯f,O2o=0 h¯f,CO2o=393520kJ/kmol

Refer Table A-22, obtain the value of h¯COo at temperature of 298K.

h¯COo=8669kJ/kmol

Refer Table A-22, obtain the value of h¯CO and s¯CO at temperature of 1800K.

h¯CO=58191 kJ/kmols¯CO=254.797kJ/kmolK

Refer Table A-19, obtain the value of h¯O2o at temperature of 298K.

h¯O2o=8682kJ/kmol

Refer Table A-19, obtain the value of h¯O2 and s¯O2 at temperature of 1800K.

h¯O2=60371kJ/kmols¯O2=264.701kJ/kmolK

Refer Table A-23, obtain the value of h¯CO2o at temperature of 298K.

h¯CO2o=9364 kJ/kmol

Refer Table A-23, obtain the value of h¯CO2 and s¯CO2 at temperature of 1800 K.

h¯CO2o=88806 kJ/kmols¯CO2=302.884 kJ/kmolK

Substitute 1 for vCO2, 393520kJ/kmol for h¯fo,CO2, 88806 kJ/kmol for h¯CO2, 9364kJ/kmol for h¯oCO2, 1800 K for T, 302.884 kJ/kmolK for s¯CO2, 1 for vCO, 110530 kJ/kmol for h¯f,COo, 58191 kJ/kmol for h¯CO, 8669 kJ/kmol for h¯oCO, 254.797 kJ/kmolK for s¯CO, 0.5 for vO2, 0 for h¯fo,O2, 60371 kJ/kmol for h¯O2, 8682 kJ/kmol for h¯oO2, 264.701 kJ/kmolK for s¯O2 in Equation (IV).

ΔG*(T)=[1(110530kJ/kmol+58191 kJ/kmol8669kJ/kmol1800 K×254.797 kJ/kmolK)+0.5(0+(60371 kJ/kmol8682 kJ/kmol)1800K×264.701 kJ/kmolK)1(393520+88806 kJ/kmol9364 kJ/kmol1800K×302.884 kJ/kmolK)]=127240.2 kJ/kmol

Substitute 127240.2 kJ/kmol for ΔG*(T), 1800 K for T, and 8.314kJ/kmolK for Ru in Equation (V).

lnKP=127240.2 kJ/kmol(8.314kJ/kmolK)×1800K=8.502

Substitute 8.502 for KP in Equation (VI).

KP=e(8.502)=2.03×104

Thus, the equilibrium constant obtained from the equilibrium reaction at 1800Kis 2.03×104.

The value obtained for equilibrium constant at 1800K from the definition of the equilibrium constant is 8.502 which is almost equal to the value obtained for equilibrium constant as 8.497 from Table A-28.

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Chapter 16 Solutions

Thermodynamics: An Engineering Approach

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