To determine the Δ r H ° , Δ r G ° and Δ r S ° for the production of hydrogen by reaction of carbon and water. Concept introduction: The Gibbs free energy or the free energy change is a thermodynamic quantity represented by Δ r G ∘ . The expression for the free energy change is: Δ r G ° = ∑ n Δ f G ° ( products ) − ∑ n Δ f G ° ( reactants ) The expression for the enthalpy change is: Δ r H ° = ∑ n Δ f H ° ( products ) − ∑ n Δ f H ° ( reactants ) The expression for the entropy change is: Δ r S ° = ∑ n S ° ( products ) − ∑ n S ° ( reactants )

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Answer 1

Question

Chapter 21, Problem 18PS

Interpretation Introduction

Interpretation:

To determine the ΔrH°,ΔrG° and ΔrS° for the production of hydrogen by reaction of carbon and water.

Concept introduction:

The Gibbs free energy or the free energy change is a thermodynamic quantity represented by ΔrG∘. The expression for the free energy change is:

ΔrG°=∑nΔfG°(products)−∑nΔfG°(reactants)

The expression for the enthalpy change is:

ΔrH°=∑nΔfH°(products)−∑nΔfH°(reactants)

The expression for the entropy change is:

ΔrS°=∑nS°(products)−∑nS°(reactants)

Expert Solution & Answer

Answer to Problem 18PS

The value of ΔrG° for the production of hydrogen by reaction of carbon and water is

+91.42 kJ/mol-rxn.

The value of ΔrH° for the production of hydrogen by reaction of carbon and water is

+130.30 kJ/mol-rxn.

The value of ΔrS° for the production of hydrogen by reaction of carbon and water is

+133.93 J/K⋅mol-rxn.

Explanation of Solution

The ΔrG°,ΔrH° and ΔrS° for the given reaction is calculated below.

Given:

Refer to Appendix L for the values of standard free energy values.

The given reaction is,

C(s) + H2O(g)⇄CO(g)+H2(g)

The ΔrG° for C(s) is 0 kJ/mol.

The ΔrG° for H2O(g) is −228.59 kJ/mol.

The ΔrG° for CO(g) is −137.168 kJ/mol.

The ΔrG° for H2(g) is 0 kJ/mol.

The expression for the free energy change is:

ΔrG°=∑nΔfG°(products)−∑nΔfG°(reactants)=[[(1 mol CO(g)/mol-rxn)ΔfG°[CO(g)]+(1 mol H2(g)/mol-rxn)ΔfG°[H2(g)]]−[(1 mol C(s)/mol-rxn)ΔfG°[C(s)]+(1 mol H2O(g)/mol-rxn)ΔfG°[H2O(g)]] ]

Substitute the values,

ΔrG°=[[(1 mol CO(g)/mol-rxn)(−137.168 kJ/mol)+(1 mol H2(g)/mol-rxn)(0 kJ/mol)]−[(1 mol C(s)/mol-rxn)(0 kJ/mol)+(1 mol H2O(g)/mol-rxn)(−228.59 kJ/mol)] ]=+91.42 kJ/mol-rxn

The ΔrH° for C(s) is 0 kJ/mol.

The ΔrH° for H2O(g) is −241.83 kJ/mol.

The ΔrH° for CO(g) is −110.525 kJ/mol.

The ΔrH° for H2(g) is 0 kJ/mol.

The expression for the enthalpy change is:

ΔrH°=∑nΔfH°(products)−∑nΔfH°(reactants)=[[(1 mol CO(g)/mol-rxn)ΔfH°[CO(g)]+(1 mol H2(g)/mol-rxn)ΔfH°[H2(g)]]−[(1 mol C(s)/mol-rxn)ΔfH°[C(s)]+(1 mol H2O(g)/mol-rxn)ΔfH°[H2O(g)]] ]

Substitute the values,

ΔH°=[[(1 mol CO(g)/mol-rxn)(−110.525 kJ/mol)+(1 mol H2(g)/mol-rxn)(0 kJ/mol)]−[(1 mol C(s)/mol-rxn)(0 kJ/mol)+(1 mol H2O(g)/mol-rxn)(−241.83 kJ/mol)] ]=+131.30 kJ/mol-rxn

The S° for C(s) is 5.6 J/K⋅mol.

The S° for H2O(g) is 188.84 J/K⋅mol.

The S° for CO(g) is 197.674 J/K⋅mol.

The S° for H2(g) is 130.7 J/K⋅mol.

The expression for the entropy change is:

ΔrS°=∑nS°(products)−∑nS°(reactants)=[[(1 mol CO(g)/mol-rxn)S°[CO(g)]+(1 mol H2(g)/mol-rxn)S°[H2(g)]]−[(1 mol C(s)/mol-rxn)S°[C(s)]+(1 mol H2O(g)/mol-rxn)S°[H2O(g)]] ]

Substitute the values,

ΔrS°=[[(1 mol CO(g)/mol-rxn)(197.674 J/K⋅mol)+(1 mol H2(g)/mol-rxn)(130.7 J/K⋅mol)]−[(1 mol C(s)/mol-rxn)(5.6 J/K⋅mol)+(1 mol H2O(g)/mol-rxn)(188.84 J/K⋅mol)] ]=133.93 J/K⋅mol-rxn

Conclusion

The value of ΔrG° for the production of hydrogen by reaction of carbon and water is

+91.42 kJ/mol-rxn.

The value of ΔrH° for the production of hydrogen by reaction of carbon and water is

+130.30 kJ/mol-rxn.

The value of ΔrS° for the production of hydrogen by reaction of carbon and water is

+133.93 J/K⋅mol-rxn.

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Answer 2

Question

Chapter 21, Problem 18PS

Interpretation Introduction

Interpretation:

To determine the ΔrH°,ΔrG° and ΔrS° for the production of hydrogen by reaction of carbon and water.

Concept introduction:

The Gibbs free energy or the free energy change is a thermodynamic quantity represented by ΔrG∘. The expression for the free energy change is:

ΔrG°=∑nΔfG°(products)−∑nΔfG°(reactants)

The expression for the enthalpy change is:

ΔrH°=∑nΔfH°(products)−∑nΔfH°(reactants)

The expression for the entropy change is:

ΔrS°=∑nS°(products)−∑nS°(reactants)

Expert Solution & Answer

Answer to Problem 18PS

The value of ΔrG° for the production of hydrogen by reaction of carbon and water is

+91.42 kJ/mol-rxn.

The value of ΔrH° for the production of hydrogen by reaction of carbon and water is

+130.30 kJ/mol-rxn.

The value of ΔrS° for the production of hydrogen by reaction of carbon and water is

+133.93 J/K⋅mol-rxn.

Explanation of Solution

The ΔrG°,ΔrH° and ΔrS° for the given reaction is calculated below.

Given:

Refer to Appendix L for the values of standard free energy values.

The given reaction is,

C(s) + H2O(g)⇄CO(g)+H2(g)

The ΔrG° for C(s) is 0 kJ/mol.

The ΔrG° for H2O(g) is −228.59 kJ/mol.

The ΔrG° for CO(g) is −137.168 kJ/mol.

The ΔrG° for H2(g) is 0 kJ/mol.

The expression for the free energy change is:

ΔrG°=∑nΔfG°(products)−∑nΔfG°(reactants)=[[(1 mol CO(g)/mol-rxn)ΔfG°[CO(g)]+(1 mol H2(g)/mol-rxn)ΔfG°[H2(g)]]−[(1 mol C(s)/mol-rxn)ΔfG°[C(s)]+(1 mol H2O(g)/mol-rxn)ΔfG°[H2O(g)]] ]

Substitute the values,

ΔrG°=[[(1 mol CO(g)/mol-rxn)(−137.168 kJ/mol)+(1 mol H2(g)/mol-rxn)(0 kJ/mol)]−[(1 mol C(s)/mol-rxn)(0 kJ/mol)+(1 mol H2O(g)/mol-rxn)(−228.59 kJ/mol)] ]=+91.42 kJ/mol-rxn

The ΔrH° for C(s) is 0 kJ/mol.

The ΔrH° for H2O(g) is −241.83 kJ/mol.

The ΔrH° for CO(g) is −110.525 kJ/mol.

The ΔrH° for H2(g) is 0 kJ/mol.

The expression for the enthalpy change is:

ΔrH°=∑nΔfH°(products)−∑nΔfH°(reactants)=[[(1 mol CO(g)/mol-rxn)ΔfH°[CO(g)]+(1 mol H2(g)/mol-rxn)ΔfH°[H2(g)]]−[(1 mol C(s)/mol-rxn)ΔfH°[C(s)]+(1 mol H2O(g)/mol-rxn)ΔfH°[H2O(g)]] ]

Substitute the values,

ΔH°=[[(1 mol CO(g)/mol-rxn)(−110.525 kJ/mol)+(1 mol H2(g)/mol-rxn)(0 kJ/mol)]−[(1 mol C(s)/mol-rxn)(0 kJ/mol)+(1 mol H2O(g)/mol-rxn)(−241.83 kJ/mol)] ]=+131.30 kJ/mol-rxn

The S° for C(s) is 5.6 J/K⋅mol.

The S° for H2O(g) is 188.84 J/K⋅mol.

The S° for CO(g) is 197.674 J/K⋅mol.

The S° for H2(g) is 130.7 J/K⋅mol.

The expression for the entropy change is:

ΔrS°=∑nS°(products)−∑nS°(reactants)=[[(1 mol CO(g)/mol-rxn)S°[CO(g)]+(1 mol H2(g)/mol-rxn)S°[H2(g)]]−[(1 mol C(s)/mol-rxn)S°[C(s)]+(1 mol H2O(g)/mol-rxn)S°[H2O(g)]] ]

Substitute the values,

ΔrS°=[[(1 mol CO(g)/mol-rxn)(197.674 J/K⋅mol)+(1 mol H2(g)/mol-rxn)(130.7 J/K⋅mol)]−[(1 mol C(s)/mol-rxn)(5.6 J/K⋅mol)+(1 mol H2O(g)/mol-rxn)(188.84 J/K⋅mol)] ]=133.93 J/K⋅mol-rxn

Conclusion

The value of ΔrG° for the production of hydrogen by reaction of carbon and water is

+91.42 kJ/mol-rxn.

The value of ΔrH° for the production of hydrogen by reaction of carbon and water is

+130.30 kJ/mol-rxn.

The value of ΔrS° for the production of hydrogen by reaction of carbon and water is

+133.93 J/K⋅mol-rxn.

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Answer 3

Question

Chapter 21, Problem 18PS

Interpretation Introduction

Interpretation:

To determine the ΔrH°,ΔrG° and ΔrS° for the production of hydrogen by reaction of carbon and water.

Concept introduction:

The Gibbs free energy or the free energy change is a thermodynamic quantity represented by ΔrG∘. The expression for the free energy change is:

ΔrG°=∑nΔfG°(products)−∑nΔfG°(reactants)

The expression for the enthalpy change is:

ΔrH°=∑nΔfH°(products)−∑nΔfH°(reactants)

The expression for the entropy change is:

ΔrS°=∑nS°(products)−∑nS°(reactants)

Expert Solution & Answer

Answer to Problem 18PS

The value of ΔrG° for the production of hydrogen by reaction of carbon and water is

+91.42 kJ/mol-rxn.

The value of ΔrH° for the production of hydrogen by reaction of carbon and water is

+130.30 kJ/mol-rxn.

The value of ΔrS° for the production of hydrogen by reaction of carbon and water is

+133.93 J/K⋅mol-rxn.

Explanation of Solution

The ΔrG°,ΔrH° and ΔrS° for the given reaction is calculated below.

Given:

Refer to Appendix L for the values of standard free energy values.

The given reaction is,

C(s) + H2O(g)⇄CO(g)+H2(g)

The ΔrG° for C(s) is 0 kJ/mol.

The ΔrG° for H2O(g) is −228.59 kJ/mol.

The ΔrG° for CO(g) is −137.168 kJ/mol.

The ΔrG° for H2(g) is 0 kJ/mol.

The expression for the free energy change is:

ΔrG°=∑nΔfG°(products)−∑nΔfG°(reactants)=[[(1 mol CO(g)/mol-rxn)ΔfG°[CO(g)]+(1 mol H2(g)/mol-rxn)ΔfG°[H2(g)]]−[(1 mol C(s)/mol-rxn)ΔfG°[C(s)]+(1 mol H2O(g)/mol-rxn)ΔfG°[H2O(g)]] ]

Substitute the values,

ΔrG°=[[(1 mol CO(g)/mol-rxn)(−137.168 kJ/mol)+(1 mol H2(g)/mol-rxn)(0 kJ/mol)]−[(1 mol C(s)/mol-rxn)(0 kJ/mol)+(1 mol H2O(g)/mol-rxn)(−228.59 kJ/mol)] ]=+91.42 kJ/mol-rxn

The ΔrH° for C(s) is 0 kJ/mol.

The ΔrH° for H2O(g) is −241.83 kJ/mol.

The ΔrH° for CO(g) is −110.525 kJ/mol.

The ΔrH° for H2(g) is 0 kJ/mol.

The expression for the enthalpy change is:

ΔrH°=∑nΔfH°(products)−∑nΔfH°(reactants)=[[(1 mol CO(g)/mol-rxn)ΔfH°[CO(g)]+(1 mol H2(g)/mol-rxn)ΔfH°[H2(g)]]−[(1 mol C(s)/mol-rxn)ΔfH°[C(s)]+(1 mol H2O(g)/mol-rxn)ΔfH°[H2O(g)]] ]

Substitute the values,

ΔH°=[[(1 mol CO(g)/mol-rxn)(−110.525 kJ/mol)+(1 mol H2(g)/mol-rxn)(0 kJ/mol)]−[(1 mol C(s)/mol-rxn)(0 kJ/mol)+(1 mol H2O(g)/mol-rxn)(−241.83 kJ/mol)] ]=+131.30 kJ/mol-rxn

The S° for C(s) is 5.6 J/K⋅mol.

The S° for H2O(g) is 188.84 J/K⋅mol.

The S° for CO(g) is 197.674 J/K⋅mol.

The S° for H2(g) is 130.7 J/K⋅mol.

The expression for the entropy change is:

ΔrS°=∑nS°(products)−∑nS°(reactants)=[[(1 mol CO(g)/mol-rxn)S°[CO(g)]+(1 mol H2(g)/mol-rxn)S°[H2(g)]]−[(1 mol C(s)/mol-rxn)S°[C(s)]+(1 mol H2O(g)/mol-rxn)S°[H2O(g)]] ]

Substitute the values,

ΔrS°=[[(1 mol CO(g)/mol-rxn)(197.674 J/K⋅mol)+(1 mol H2(g)/mol-rxn)(130.7 J/K⋅mol)]−[(1 mol C(s)/mol-rxn)(5.6 J/K⋅mol)+(1 mol H2O(g)/mol-rxn)(188.84 J/K⋅mol)] ]=133.93 J/K⋅mol-rxn

Conclusion

The value of ΔrG° for the production of hydrogen by reaction of carbon and water is

+91.42 kJ/mol-rxn.

The value of ΔrH° for the production of hydrogen by reaction of carbon and water is

+130.30 kJ/mol-rxn.

The value of ΔrS° for the production of hydrogen by reaction of carbon and water is

+133.93 J/K⋅mol-rxn.

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Answer 4

Question

Chapter 21, Problem 18PS

Interpretation Introduction

Interpretation:

To determine the ΔrH°,ΔrG° and ΔrS° for the production of hydrogen by reaction of carbon and water.

Concept introduction:

The Gibbs free energy or the free energy change is a thermodynamic quantity represented by ΔrG∘. The expression for the free energy change is:

ΔrG°=∑nΔfG°(products)−∑nΔfG°(reactants)

The expression for the enthalpy change is:

ΔrH°=∑nΔfH°(products)−∑nΔfH°(reactants)

The expression for the entropy change is:

ΔrS°=∑nS°(products)−∑nS°(reactants)

Expert Solution & Answer

Answer to Problem 18PS

The value of ΔrG° for the production of hydrogen by reaction of carbon and water is

+91.42 kJ/mol-rxn.

The value of ΔrH° for the production of hydrogen by reaction of carbon and water is

+130.30 kJ/mol-rxn.

The value of ΔrS° for the production of hydrogen by reaction of carbon and water is

+133.93 J/K⋅mol-rxn.

Explanation of Solution

The ΔrG°,ΔrH° and ΔrS° for the given reaction is calculated below.

Given:

Refer to Appendix L for the values of standard free energy values.

The given reaction is,

C(s) + H2O(g)⇄CO(g)+H2(g)

The ΔrG° for C(s) is 0 kJ/mol.

The ΔrG° for H2O(g) is −228.59 kJ/mol.

The ΔrG° for CO(g) is −137.168 kJ/mol.

The ΔrG° for H2(g) is 0 kJ/mol.

The expression for the free energy change is:

ΔrG°=∑nΔfG°(products)−∑nΔfG°(reactants)=[[(1 mol CO(g)/mol-rxn)ΔfG°[CO(g)]+(1 mol H2(g)/mol-rxn)ΔfG°[H2(g)]]−[(1 mol C(s)/mol-rxn)ΔfG°[C(s)]+(1 mol H2O(g)/mol-rxn)ΔfG°[H2O(g)]] ]

Substitute the values,

ΔrG°=[[(1 mol CO(g)/mol-rxn)(−137.168 kJ/mol)+(1 mol H2(g)/mol-rxn)(0 kJ/mol)]−[(1 mol C(s)/mol-rxn)(0 kJ/mol)+(1 mol H2O(g)/mol-rxn)(−228.59 kJ/mol)] ]=+91.42 kJ/mol-rxn

The ΔrH° for C(s) is 0 kJ/mol.

The ΔrH° for H2O(g) is −241.83 kJ/mol.

The ΔrH° for CO(g) is −110.525 kJ/mol.

The ΔrH° for H2(g) is 0 kJ/mol.

The expression for the enthalpy change is:

ΔrH°=∑nΔfH°(products)−∑nΔfH°(reactants)=[[(1 mol CO(g)/mol-rxn)ΔfH°[CO(g)]+(1 mol H2(g)/mol-rxn)ΔfH°[H2(g)]]−[(1 mol C(s)/mol-rxn)ΔfH°[C(s)]+(1 mol H2O(g)/mol-rxn)ΔfH°[H2O(g)]] ]

Substitute the values,

ΔH°=[[(1 mol CO(g)/mol-rxn)(−110.525 kJ/mol)+(1 mol H2(g)/mol-rxn)(0 kJ/mol)]−[(1 mol C(s)/mol-rxn)(0 kJ/mol)+(1 mol H2O(g)/mol-rxn)(−241.83 kJ/mol)] ]=+131.30 kJ/mol-rxn

The S° for C(s) is 5.6 J/K⋅mol.

The S° for H2O(g) is 188.84 J/K⋅mol.

The S° for CO(g) is 197.674 J/K⋅mol.

The S° for H2(g) is 130.7 J/K⋅mol.

The expression for the entropy change is:

ΔrS°=∑nS°(products)−∑nS°(reactants)=[[(1 mol CO(g)/mol-rxn)S°[CO(g)]+(1 mol H2(g)/mol-rxn)S°[H2(g)]]−[(1 mol C(s)/mol-rxn)S°[C(s)]+(1 mol H2O(g)/mol-rxn)S°[H2O(g)]] ]

Substitute the values,

ΔrS°=[[(1 mol CO(g)/mol-rxn)(197.674 J/K⋅mol)+(1 mol H2(g)/mol-rxn)(130.7 J/K⋅mol)]−[(1 mol C(s)/mol-rxn)(5.6 J/K⋅mol)+(1 mol H2O(g)/mol-rxn)(188.84 J/K⋅mol)] ]=133.93 J/K⋅mol-rxn

Conclusion

The value of ΔrG° for the production of hydrogen by reaction of carbon and water is

+91.42 kJ/mol-rxn.

The value of ΔrH° for the production of hydrogen by reaction of carbon and water is

+130.30 kJ/mol-rxn.

The value of ΔrS° for the production of hydrogen by reaction of carbon and water is

+133.93 J/K⋅mol-rxn.

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Answer 5

Chapter 21, Problem 18PS

Interpretation Introduction

Interpretation:

To determine the ΔrH°,ΔrG° and ΔrS° for the production of hydrogen by reaction of carbon and water.

Concept introduction:

The Gibbs free energy or the free energy change is a thermodynamic quantity represented by ΔrG∘. The expression for the free energy change is:

ΔrG°=∑nΔfG°(products)−∑nΔfG°(reactants)

The expression for the enthalpy change is:

ΔrH°=∑nΔfH°(products)−∑nΔfH°(reactants)

The expression for the entropy change is:

ΔrS°=∑nS°(products)−∑nS°(reactants)

Expert Solution & Answer

Answer to Problem 18PS

The value of ΔrG° for the production of hydrogen by reaction of carbon and water is

+91.42 kJ/mol-rxn.

The value of ΔrH° for the production of hydrogen by reaction of carbon and water is

+130.30 kJ/mol-rxn.

The value of ΔrS° for the production of hydrogen by reaction of carbon and water is

+133.93 J/K⋅mol-rxn.

Explanation of Solution

The ΔrG°,ΔrH° and ΔrS° for the given reaction is calculated below.

Given:

Refer to Appendix L for the values of standard free energy values.

The given reaction is,

C(s) + H2O(g)⇄CO(g)+H2(g)

The ΔrG° for C(s) is 0 kJ/mol.

The ΔrG° for H2O(g) is −228.59 kJ/mol.

The ΔrG° for CO(g) is −137.168 kJ/mol.

The ΔrG° for H2(g) is 0 kJ/mol.

The expression for the free energy change is:

ΔrG°=∑nΔfG°(products)−∑nΔfG°(reactants)=[[(1 mol CO(g)/mol-rxn)ΔfG°[CO(g)]+(1 mol H2(g)/mol-rxn)ΔfG°[H2(g)]]−[(1 mol C(s)/mol-rxn)ΔfG°[C(s)]+(1 mol H2O(g)/mol-rxn)ΔfG°[H2O(g)]] ]

Substitute the values,

ΔrG°=[[(1 mol CO(g)/mol-rxn)(−137.168 kJ/mol)+(1 mol H2(g)/mol-rxn)(0 kJ/mol)]−[(1 mol C(s)/mol-rxn)(0 kJ/mol)+(1 mol H2O(g)/mol-rxn)(−228.59 kJ/mol)] ]=+91.42 kJ/mol-rxn

The ΔrH° for C(s) is 0 kJ/mol.

The ΔrH° for H2O(g) is −241.83 kJ/mol.

The ΔrH° for CO(g) is −110.525 kJ/mol.

The ΔrH° for H2(g) is 0 kJ/mol.

The expression for the enthalpy change is:

ΔrH°=∑nΔfH°(products)−∑nΔfH°(reactants)=[[(1 mol CO(g)/mol-rxn)ΔfH°[CO(g)]+(1 mol H2(g)/mol-rxn)ΔfH°[H2(g)]]−[(1 mol C(s)/mol-rxn)ΔfH°[C(s)]+(1 mol H2O(g)/mol-rxn)ΔfH°[H2O(g)]] ]

Substitute the values,

ΔH°=[[(1 mol CO(g)/mol-rxn)(−110.525 kJ/mol)+(1 mol H2(g)/mol-rxn)(0 kJ/mol)]−[(1 mol C(s)/mol-rxn)(0 kJ/mol)+(1 mol H2O(g)/mol-rxn)(−241.83 kJ/mol)] ]=+131.30 kJ/mol-rxn

The S° for C(s) is 5.6 J/K⋅mol.

The S° for H2O(g) is 188.84 J/K⋅mol.

The S° for CO(g) is 197.674 J/K⋅mol.

The S° for H2(g) is 130.7 J/K⋅mol.

The expression for the entropy change is:

ΔrS°=∑nS°(products)−∑nS°(reactants)=[[(1 mol CO(g)/mol-rxn)S°[CO(g)]+(1 mol H2(g)/mol-rxn)S°[H2(g)]]−[(1 mol C(s)/mol-rxn)S°[C(s)]+(1 mol H2O(g)/mol-rxn)S°[H2O(g)]] ]

Substitute the values,

ΔrS°=[[(1 mol CO(g)/mol-rxn)(197.674 J/K⋅mol)+(1 mol H2(g)/mol-rxn)(130.7 J/K⋅mol)]−[(1 mol C(s)/mol-rxn)(5.6 J/K⋅mol)+(1 mol H2O(g)/mol-rxn)(188.84 J/K⋅mol)] ]=133.93 J/K⋅mol-rxn

Conclusion

The value of ΔrG° for the production of hydrogen by reaction of carbon and water is

+91.42 kJ/mol-rxn.

The value of ΔrH° for the production of hydrogen by reaction of carbon and water is

+130.30 kJ/mol-rxn.

The value of ΔrS° for the production of hydrogen by reaction of carbon and water is

+133.93 J/K⋅mol-rxn.

Answer 6

Chapter 21, Problem 18PS

Interpretation Introduction

Interpretation:

To determine the ΔrH°,ΔrG° and ΔrS° for the production of hydrogen by reaction of carbon and water.

Concept introduction:

The Gibbs free energy or the free energy change is a thermodynamic quantity represented by ΔrG∘. The expression for the free energy change is:

ΔrG°=∑nΔfG°(products)−∑nΔfG°(reactants)

The expression for the enthalpy change is:

ΔrH°=∑nΔfH°(products)−∑nΔfH°(reactants)

The expression for the entropy change is:

ΔrS°=∑nS°(products)−∑nS°(reactants)

Expert Solution & Answer

Answer to Problem 18PS

The value of ΔrG° for the production of hydrogen by reaction of carbon and water is

+91.42 kJ/mol-rxn.

The value of ΔrH° for the production of hydrogen by reaction of carbon and water is

+130.30 kJ/mol-rxn.

The value of ΔrS° for the production of hydrogen by reaction of carbon and water is

+133.93 J/K⋅mol-rxn.

Explanation of Solution

The ΔrG°,ΔrH° and ΔrS° for the given reaction is calculated below.

Given:

Refer to Appendix L for the values of standard free energy values.

The given reaction is,

C(s) + H2O(g)⇄CO(g)+H2(g)

The ΔrG° for C(s) is 0 kJ/mol.

The ΔrG° for H2O(g) is −228.59 kJ/mol.

The ΔrG° for CO(g) is −137.168 kJ/mol.

The ΔrG° for H2(g) is 0 kJ/mol.

The expression for the free energy change is:

ΔrG°=∑nΔfG°(products)−∑nΔfG°(reactants)=[[(1 mol CO(g)/mol-rxn)ΔfG°[CO(g)]+(1 mol H2(g)/mol-rxn)ΔfG°[H2(g)]]−[(1 mol C(s)/mol-rxn)ΔfG°[C(s)]+(1 mol H2O(g)/mol-rxn)ΔfG°[H2O(g)]] ]

Substitute the values,

ΔrG°=[[(1 mol CO(g)/mol-rxn)(−137.168 kJ/mol)+(1 mol H2(g)/mol-rxn)(0 kJ/mol)]−[(1 mol C(s)/mol-rxn)(0 kJ/mol)+(1 mol H2O(g)/mol-rxn)(−228.59 kJ/mol)] ]=+91.42 kJ/mol-rxn

The ΔrH° for C(s) is 0 kJ/mol.

The ΔrH° for H2O(g) is −241.83 kJ/mol.

The ΔrH° for CO(g) is −110.525 kJ/mol.

The ΔrH° for H2(g) is 0 kJ/mol.

The expression for the enthalpy change is:

ΔrH°=∑nΔfH°(products)−∑nΔfH°(reactants)=[[(1 mol CO(g)/mol-rxn)ΔfH°[CO(g)]+(1 mol H2(g)/mol-rxn)ΔfH°[H2(g)]]−[(1 mol C(s)/mol-rxn)ΔfH°[C(s)]+(1 mol H2O(g)/mol-rxn)ΔfH°[H2O(g)]] ]

Substitute the values,

ΔH°=[[(1 mol CO(g)/mol-rxn)(−110.525 kJ/mol)+(1 mol H2(g)/mol-rxn)(0 kJ/mol)]−[(1 mol C(s)/mol-rxn)(0 kJ/mol)+(1 mol H2O(g)/mol-rxn)(−241.83 kJ/mol)] ]=+131.30 kJ/mol-rxn

The S° for C(s) is 5.6 J/K⋅mol.

The S° for H2O(g) is 188.84 J/K⋅mol.

The S° for CO(g) is 197.674 J/K⋅mol.

The S° for H2(g) is 130.7 J/K⋅mol.

The expression for the entropy change is:

ΔrS°=∑nS°(products)−∑nS°(reactants)=[[(1 mol CO(g)/mol-rxn)S°[CO(g)]+(1 mol H2(g)/mol-rxn)S°[H2(g)]]−[(1 mol C(s)/mol-rxn)S°[C(s)]+(1 mol H2O(g)/mol-rxn)S°[H2O(g)]] ]

Substitute the values,

ΔrS°=[[(1 mol CO(g)/mol-rxn)(197.674 J/K⋅mol)+(1 mol H2(g)/mol-rxn)(130.7 J/K⋅mol)]−[(1 mol C(s)/mol-rxn)(5.6 J/K⋅mol)+(1 mol H2O(g)/mol-rxn)(188.84 J/K⋅mol)] ]=133.93 J/K⋅mol-rxn

Conclusion

The value of ΔrG° for the production of hydrogen by reaction of carbon and water is

+91.42 kJ/mol-rxn.

The value of ΔrH° for the production of hydrogen by reaction of carbon and water is

+130.30 kJ/mol-rxn.

The value of ΔrS° for the production of hydrogen by reaction of carbon and water is

+133.93 J/K⋅mol-rxn.

Answer 7

Chapter 21, Problem 18PS

Interpretation Introduction

Interpretation:

To determine the ΔrH°,ΔrG° and ΔrS° for the production of hydrogen by reaction of carbon and water.

Concept introduction:

The Gibbs free energy or the free energy change is a thermodynamic quantity represented by ΔrG∘. The expression for the free energy change is:

ΔrG°=∑nΔfG°(products)−∑nΔfG°(reactants)

The expression for the enthalpy change is:

ΔrH°=∑nΔfH°(products)−∑nΔfH°(reactants)

The expression for the entropy change is:

ΔrS°=∑nS°(products)−∑nS°(reactants)

Answer 8

Expert Solution & Answer

Answer to Problem 18PS

The value of ΔrG° for the production of hydrogen by reaction of carbon and water is

+91.42 kJ/mol-rxn.

The value of ΔrH° for the production of hydrogen by reaction of carbon and water is

+130.30 kJ/mol-rxn.

The value of ΔrS° for the production of hydrogen by reaction of carbon and water is

+133.93 J/K⋅mol-rxn.

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

Explanation of Solution

The ΔrG°,ΔrH° and ΔrS° for the given reaction is calculated below.

Given:

Refer to Appendix L for the values of standard free energy values.

The given reaction is,

C(s) + H2O(g)⇄CO(g)+H2(g)

The ΔrG° for C(s) is 0 kJ/mol.

The ΔrG° for H2O(g) is −228.59 kJ/mol.

The ΔrG° for CO(g) is −137.168 kJ/mol.

The ΔrG° for H2(g) is 0 kJ/mol.

The expression for the free energy change is:

ΔrG°=∑nΔfG°(products)−∑nΔfG°(reactants)=[[(1 mol CO(g)/mol-rxn)ΔfG°[CO(g)]+(1 mol H2(g)/mol-rxn)ΔfG°[H2(g)]]−[(1 mol C(s)/mol-rxn)ΔfG°[C(s)]+(1 mol H2O(g)/mol-rxn)ΔfG°[H2O(g)]] ]

Substitute the values,

ΔrG°=[[(1 mol CO(g)/mol-rxn)(−137.168 kJ/mol)+(1 mol H2(g)/mol-rxn)(0 kJ/mol)]−[(1 mol C(s)/mol-rxn)(0 kJ/mol)+(1 mol H2O(g)/mol-rxn)(−228.59 kJ/mol)] ]=+91.42 kJ/mol-rxn

The ΔrH° for C(s) is 0 kJ/mol.

The ΔrH° for H2O(g) is −241.83 kJ/mol.

The ΔrH° for CO(g) is −110.525 kJ/mol.

The ΔrH° for H2(g) is 0 kJ/mol.

The expression for the enthalpy change is:

ΔrH°=∑nΔfH°(products)−∑nΔfH°(reactants)=[[(1 mol CO(g)/mol-rxn)ΔfH°[CO(g)]+(1 mol H2(g)/mol-rxn)ΔfH°[H2(g)]]−[(1 mol C(s)/mol-rxn)ΔfH°[C(s)]+(1 mol H2O(g)/mol-rxn)ΔfH°[H2O(g)]] ]

Substitute the values,

ΔH°=[[(1 mol CO(g)/mol-rxn)(−110.525 kJ/mol)+(1 mol H2(g)/mol-rxn)(0 kJ/mol)]−[(1 mol C(s)/mol-rxn)(0 kJ/mol)+(1 mol H2O(g)/mol-rxn)(−241.83 kJ/mol)] ]=+131.30 kJ/mol-rxn

The S° for C(s) is 5.6 J/K⋅mol.

The S° for H2O(g) is 188.84 J/K⋅mol.

The S° for CO(g) is 197.674 J/K⋅mol.

The S° for H2(g) is 130.7 J/K⋅mol.

The expression for the entropy change is:

ΔrS°=∑nS°(products)−∑nS°(reactants)=[[(1 mol CO(g)/mol-rxn)S°[CO(g)]+(1 mol H2(g)/mol-rxn)S°[H2(g)]]−[(1 mol C(s)/mol-rxn)S°[C(s)]+(1 mol H2O(g)/mol-rxn)S°[H2O(g)]] ]

Substitute the values,

ΔrS°=[[(1 mol CO(g)/mol-rxn)(197.674 J/K⋅mol)+(1 mol H2(g)/mol-rxn)(130.7 J/K⋅mol)]−[(1 mol C(s)/mol-rxn)(5.6 J/K⋅mol)+(1 mol H2O(g)/mol-rxn)(188.84 J/K⋅mol)] ]=133.93 J/K⋅mol-rxn