Bundle: Chemistry: The Molecular Science, 5th, Loose-Leaf + OWLv2 with Quick Prep 24-Months Printed Access Card
Bundle: Chemistry: The Molecular Science, 5th, Loose-Leaf + OWLv2 with Quick Prep 24-Months Printed Access Card
5th Edition
ISBN: 9781305367487
Author: John W. Moore, Conrad L. Stanitski
Publisher: Cengage Learning
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Chapter 16, Problem 77QRT

(a)

Interpretation Introduction

Interpretation:

The minimum mass of graphite that would have to be oxidized to carbon dioxide to provide the necessary work has to be calculated.

Concept Introduction:

The Gibbs free energy of a system is defined as the Gibbs free energy of product minus Gibbs free energy of reactants.  The Gibbs free energy of the system is a state function as it is defined in terms of thermodynamic properties that are state functions.

(a)

Expert Solution
Check Mark

Answer to Problem 77QRT

The given reaction is capable of being harnessed to do the useful work.

Explanation of Solution

The given reaction is shown below.

  2C6H6(l)+15O2(g)12CO2(g)+6H2O(g)

The value of ΔrG° is calculated by the formula shown below.

    ΔrG°=nProductsΔfG°(Products)nReactantsΔfG°(Reactants)        (1)

Where,

  • ΔfG° is the change in standard Gibbs free energy of formation.
  • nReactants is the number of moles of reactants.
  • nProducts is the number of moles of products.

The value of ΔfG° for CO2(g), H2O(g), C6H6(l) and O2(g) is 394.359kJ/mol, 228.572kJ/mol, 124.5kJ/mol and 0kJ/mol respectively.

Substitute the values in equation (1) as shown below.

    ΔrG°=((nCO2(g)×ΔfG°(CO2(g))+nH2O(g)×ΔfG°(H2O(g)))(nC6H6(l)×ΔfG°(C6H6(l))+nO2(g)×ΔfG°(O2(g))))=((12×(394.359kJ/mol)+6×(228.572kJ/mol))(2×(124.5kJ/mol)+15×(0kJ/mol)))=((4732.308kJ/mol1371.432kJ/mol)249kJ/mol)=6352.74kJ/mol

The value of Gibbs free energy is negative.  Therefore, the reaction is product favored and the reaction can do upto 6352.74kJ/mol work.

(b)

Interpretation Introduction

Interpretation:

The minimum mass of graphite that would have to be oxidized to carbon dioxide to provide the necessary work has to be calculated.

Concept Introduction:

Refer to part (a).

(b)

Expert Solution
Check Mark

Answer to Problem 77QRT

The minimum mass of graphite that would have to be oxidized to carbon dioxide to provide the necessary work is 5.063 g_.

Explanation of Solution

The given reaction is shown below.

  2NF3(g)N2(g)+3F2(g)

The value of ΔrG° is calculated by the formula shown below.

    ΔrG°=nProductsΔfG°(Products)nReactantsΔfG°(Reactants)        (1)

Where,

  • ΔfG° is the change in standard Gibbs free energy of formation.
  • nReactants is the number of moles of reactants.
  • nProducts is the number of moles of products.

The value of ΔfG° for N2(g), F2(g), and NF3(g) is 0kJ/mol, 0kJ/mol, and 83.2kJ/mol respectively.

Substitute the values in equation (1) as shown below.

    ΔrG°=((nN2(g)×ΔfG°(N2(g))+nF2(g)×ΔfG°(F2(g)))(nNF3(g)×ΔfG°(NF3(g))))=((1×(0kJ/mol)+3×(0kJ/mol))(2×(83.2kJ/mol)))=166.4kJ/mol

The value of Gibbs free energy is positive.  Therefore, the reaction is reactant favored and the reaction requires 166.4kJ/mol work.

The reaction for the combustion of carbon is shown below.

    C(graphite)+O2(g)CO2(g)

The value of ΔfG° for CO2(g), C(graphite), and O2(g) is 394.359kJ/mol, 0kJ/mol, and 0kJ/mol respectively.

Substitute the values in equation (1) as shown below.

    ΔrG°=((nCO2(g)×ΔfG°(CO2(g)))(nC(graphite)×ΔfG°(C(graphite))+nO2(g)×ΔfG°(O2(g))))=((1×394.359kJ/mol)(1×0kJ/mol+1×0kJ/mol))=394.359kJ/mol

The Gibbs energy required for the conversion of graphite to carbon monoxide is 394.359kJ/mol.

The number of moles required to provide the necessary work is calculated by the formula shown below.

    Number of moles=Gibbs energy for decomposition of NF3(g)Gibbs energy for combustion of graphite

Substitute the value of Gibbs energy for decomposition of NF3(g) and combustion of graphite in the above equation.

    Number of moles=Gibbs energy for decomposition of NF3(g)Gibbs energy for combustion of graphite=166.4kJ/mol394.359kJ/mol=0.4219

Mass of carbon required is calculated by the formula shown below.

    Mass=Molar mass×Number of moles

The molar mass of carbon is 12 g/mol.

Substitute the value of molar mass and number of moles in the above equation.

    Mass=12 g/mol×0.4219 mol=5.063 g_

Thus, the minimum mass of graphite that would have to be oxidized to carbon dioxide to provide the necessary work is 5.063 g_.

(c)

Interpretation Introduction

Interpretation:

The minimum mass of graphite that would have to be oxidized to carbon dioxide to provide the necessary work has to be calculated.

Concept Introduction:

Refer to part (a).

(c)

Expert Solution
Check Mark

Answer to Problem 77QRT

The minimum mass of graphite that would have to be oxidized to carbon dioxide to provide the necessary work is 26.88 g_.

Explanation of Solution

The given reaction is shown below.

  TiO2(s)Ti(s)+O2(g)

The value of ΔrG° is calculated by the formula shown below.

    ΔrG°=nProductsΔfG°(Products)nReactantsΔfG°(Reactants)        (1)

Where,

  • ΔfG° is the change in standard Gibbs free energy of formation.
  • nReactants is the number of moles of reactants.
  • nProducts is the number of moles of products.

The value of ΔfG° for Ti(s), O2(g), and TiO2(s) is 0kJ/mol, 0kJ/mol, and 884.5kJ/mol respectively.

Substitute the values in equation (1) as shown below.

    ΔrG°=((nTi(s)×ΔfG°(Ti(s))+nO2(g)×ΔfG°(O2(g)))(nTiO2(s)×ΔfG°(TiO2(s))))=((1×(0kJ/mol)+1×(0kJ/mol))(1×(884.5kJ/mol)))=884.5kJ/mol

The value of Gibbs free energy is positive.  Therefore, the reaction is reactant favored and the reaction requires 884.5kJ/mol work.

The reaction for the combustion of carbon is shown below.

    C(graphite)+O2(g)CO2(g)

The value of ΔfG° for CO2(g), C(graphite), and O2(g) is 394.359kJ/mol, 0kJ/mol, and 0kJ/mol respectively.

Substitute the values in equation (1) as shown below.

    ΔrG°=((nCO2(g)×ΔfG°(CO2(g)))(nC(graphite)×ΔfG°(C(graphite))+nO2(g)×ΔfG°(O2(g))))=((1×394.359kJ/mol)(1×0kJ/mol+1×0kJ/mol))=394.359kJ/mol

The Gibbs energy required for the conversion of graphite to carbon monoxide is 394.359kJ/mol.

The number of moles required to provide the necessary work is calculated by the formula shown below.

    Number of moles=Gibbs energy for decomposition of TiO2(s)Gibbs energy for combustion of graphite

Substitute the value of Gibbs energy for decomposition of TiO2(s) and combustion of graphite in the above equation.

    Number of moles=Gibbs energy for decomposition of NF3(g)Gibbs energy for combustion of graphite=884.5kJ/mol394.359kJ/mol=2.24

Mass of carbon required is calculated by the formula shown below.

    Mass=Molar mass×Number of moles

The molar mass of carbon is 12 g/mol.

Substitute the value of molar mass and number of moles in the above equation.

    Mass=12 g/mol×2.24 mol=26.88 g_

Thus, the minimum mass of graphite that would have to be oxidized to carbon dioxide to provide the necessary work is 26.88 g_.

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Chapter 16 Solutions

Bundle: Chemistry: The Molecular Science, 5th, Loose-Leaf + OWLv2 with Quick Prep 24-Months Printed Access Card

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