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Science Chemistry Student Solutions Manual for Ebbing/Gammon's General Chemistry, 11th

The equilibrium constant of given cell reaction should be calculated by using standard reduction potentials. Concept introduction: Cell potential (EMF): The maximum potential difference between two electrodes in the voltaic cell is known as cell potential. If standard reduction potentials of electrodes are given the cell potential (EMF) is given by, E cell = E cathode -E anode Where, E cathode is the reduction half cell potential E anode is the oxidation half cell potential Equilibrium constant K c : The relationship between equilibrium constant and cell potential (EMF) is given by below equation E cell = RT nF lnK c Where, K c is equilibrium constant n is number of electron transferred F is faraday constant E cell is cell potential R is gas constant(8 .314J/mol K) T is temprrature (25°C)

The equilibrium constant of given cell reaction should be calculated by using standard reduction potentials. Concept introduction: Cell potential (EMF): The maximum potential difference between two electrodes in the voltaic cell is known as cell potential. If standard reduction potentials of electrodes are given the cell potential (EMF) is given by, E cell = E cathode -E anode Where, E cathode is the reduction half cell potential E anode is the oxidation half cell potential Equilibrium constant K c : The relationship between equilibrium constant and cell potential (EMF) is given by below equation E cell = RT nF lnK c Where, K c is equilibrium constant n is number of electron transferred F is faraday constant E cell is cell potential R is gas constant(8 .314J/mol K) T is temprrature (25°C)

Solution Summary: The author explains that the equilibrium constant of given cell reaction should be calculated by using standard reduction potentials.

Student Solutions Manual for Ebbing/Gammon's General Chemistry, 11th

Student Solutions Manual for Ebbing/Gammon's General Chemistry, 11th

11th Edition

ISBN: 9781305673472

Author: Darrell Ebbing, Steven D. Gammon

Publisher: Cengage Learning

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Chapter 19.6, Problem 19.12E

Interpretation Introduction

Interpretation:

The equilibrium constant of given cell reaction should be calculated by using standard reduction potentials.

Concept introduction:

Cell potential (EMF):

The maximum potential difference between two electrodes in the voltaic cell is known as cell potential.

If standard reduction potentials of electrodes are given the cell potential (EMF) is given by,

Ecell= Ecathode-Eanode

Where,

Ecathode is the reduction half cell potentialEanode is the oxidation half cell potential

Equilibrium constant Kc :

The relationship between equilibrium constant and cell potential (EMF) is given by below equation

Ecell= RTnFlnKc

Where,

Kc is equilibrium constantn is number of electron transferredF is faraday constantEcell is cell potentialR is gas constant(8.314J/mol K)T is temprrature (25°C)

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Chapter 19.6, Problem 19.11E

Chapter 19.7, Problem 19.13E

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Chapter 19 Solutions

Student Solutions Manual for Ebbing/Gammon's General Chemistry, 11th

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