Chemistry: An Atoms First Approach
Chemistry: An Atoms First Approach
2nd Edition
ISBN: 9781305079243
Author: Steven S. Zumdahl, Susan A. Zumdahl
Publisher: Cengage Learning
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Chapter 17, Problem 144CP

(a)

Interpretation Introduction

Interpretation: The cell potential Ecell of the given cell, the mass of each electrode after 10.0 h and the time of the given battery to deliver a current of 10.0 A before it goes dead is to be calculated.

Concept introduction: Cell potential is defined as the measure of energy per unit charge available from the redox reaction to carry out the reaction. The electrochemical equivalent is defined as the mass of the element transported when electricity of one coulomb charge is passed.

To determine: The cell potential of the given cell when the battery is connected.

(a)

Expert Solution
Check Mark

Answer to Problem 144CP

Answer

The cell potential of the given cell when the battery is connected is 1.141 V_ .

Explanation of Solution

Explanation

Given

The molar concentration of Zn2+ is (0.10 M) .

The molar concentration of Cu2+ is (2.50 M) .

The half cell reactions for the cell are,

    Zn+2+2eZn                      E1ο=0.76 V (1)

     Cu+2+2eCu                          E2ο=0.34 V (2)

Where,

  • E1ο is the standard electrode potential of equation (1).
  • E2ο is the standard electrode potential of equation (2).

The overall cell reaction is,

Zn+Cu+2Zn2++Cu (3)

The standard electrode potential of equation (3) is calculated by the formula,

Ecellο=E2οE1ο

Where,

  • Ecellο is the standard electrode potential of equation (3).

Substitute the values of E1ο and E2ο in the above formula.

Ecellο=0.34 V(0.76 V)=1.10 V

The cell potential after connecting the battery is calculated by using Nernst equation.

Ecell=Ecellο0.0591nlog([Zn+2][Cu+2])

Where,

  • n is the number of electrons in the cell reaction.

Substitute the values of n , molar concentrations of anode and cathode and Ecellο in the above expression.

Ecell=Ecellο0.0591nlog([Zn+2][Cu+2])=1.10 V0.05912log([0.10][2.50])=1.10 V(0.041)=1.141 V_

Hence, the cell potential of the given cell when the battery is connected is 1.141 V_ .

(b)

Interpretation Introduction

Interpretation: The cell potential Ecell of the given cell, the mass of each electrode after 10.0 h and the time of the given battery to deliver a current of 10.0 A before it goes dead is to be calculated.

Concept introduction: Cell potential is defined as the measure of energy per unit charge available from the redox reaction to carry out the reaction. The electrochemical equivalent is defined as the mass of the element transported when electricity of one coulomb charge is passed.

To determine: The cell potential after 10.0 A of current has flowed for 10.0 h .

(b)

Expert Solution
Check Mark

Answer to Problem 144CP

Answer

The cell potential after 10.0 A of current has flowed for 10.0 h is 1.09 V_ .

Explanation of Solution

Explanation

Given

The initial concentration of zinc is (0.10 M) .

The atomic weight of zinc is 65.41 g/mol .

The volume of solution is 1.00 L .

The time is 1 hr .

The conversion of 1 hr to sec is done as,

1 hr=60 min=60×60 sec=3600 sec

Therefore the conversion of 10 hr to sec is done as,

1 hr=3600 sec10 hr=10×3600 sec

The first step is to calculate the new concentrations of Zn2+ and Cu2+ . This is done by calculating the change in the number of moles of Zn2+ and Cu2+ that result from passing a current of 10.0 A for 10 hours by using the given expression.

Q(C)=I(A)×t(s) .

Where,

  • Q is the total charge.
  • I is the current.
  • t is the time.

Substitute the value of current and time in the above expression.

Q(C)=I(A)×t(s)=10.0 A×10.0×3600 s=3.60×105 C

Thus, the number of moles of charge passed is calculated by using the expression,

Number of moles=Given chargeF .

Where,

  • F is the Faradays constant (F=96,485 C/mol) .

Substitute the value of charge and F in the above expression to calculate the number of moles of charge passed.

Number of moles=Given chargeF=3.60×105 C96,485 C/mol=3.73 mol

Since two moles of electrons are involved in the reaction. The number of moles of Cu2+ consumed is half of the number of moles of Zn2+ produced.

Number of moles of Cu2+=Number of moles of Zn2+2=3.73 mol2=1.865 mol .

Initially in a 1.00 L solution, (2.50 M) moles of Cu2+ and (0.10 M) moles of Zn2+ are given. After 10 hours, the concentration of Cu2+ and Zn2+ is calculated as,

[Cu2+]=2.50 M1.865 M=0.635 M

[Zn2+]=0.10 M+1.865 M=1.965 M .

Thus, after 10.0 hours Q=([Zn2+]Cu2+)=(1.9650.635)=(3.09 M) .

The cell potential after 10.0 A of current is calculated by using Nernst equation.

Ecell=Ecellο0.0591nlog([Zn+2][Cu+2])=1.10 V0.05912log(3.09)=1.10 V1.45×102 V=1.09 V_

Hence, the cell potential after 10.0 A of current has flowed for 10.0 h is 1.09 V_ .

(c)

Interpretation Introduction

Interpretation: The cell potential Ecell of the given cell, the mass of each electrode after 10.0 h and the time of the given battery to deliver a current of 10.0 A before it goes dead is to be calculated.

Concept introduction: Cell potential is defined as the measure of energy per unit charge available from the redox reaction to carry out the reaction. The electrochemical equivalent is defined as the mass of the element transported when electricity of one coulomb charge is passed.

To determine: The mass of each electrode after 10.0 h .

(c)

Expert Solution
Check Mark

Answer to Problem 144CP

Answer

The mass of copper electrode after 10.0 h is 82.5 g_ .

The mass of zinc electrode after 10.0 h is 78.32 g_ .

Explanation of Solution

Explanation

Given

Current (C) is 10.0 A .

Time is 10.0 h .

The conversion of 1 hr to sec is done as,

1 hr=60 min=60×60 sec=3600 sec

Therefore, the conversion of 10 hr to sec is done as,

1 hr=3600 sec10 hr=10×3600 sec

The equivalent weight of copper is calculated by using the given expression,

Equivalent weight=Atomic weightValancy .

The atomic weight of Copper is 63 amu .

Substitute the value of atomic weight and valancy of copper in the above expression to calculate its equivalent weight,

Equivalent weight=Atomic weightValancy=632=31.5

Hence, electrochemical equivalent (Z) is calculated as,

Z=Equivalent weightF=31.596485=3.2×104 .

The weight of copper deposited is calculated by using the given expression,

W=Z×c×t .

Where,

  • Z is the electrochemical equivalent.
  • c is the charge.
  • t is the time in sec.

Substitute the value of Z , c and t in the above expression to calculate the weight of copper deposited.

W=Z×c×t=3.2×104×10×3600=117.5 g

If the weight of copper deposited in 10 hr is 117.5 g . Then the weight of copper electrode after 10 hr is calculated as,

Weight of Cu electrode=Total mass of electrodeWeight of Cu in 10hr=200117.5=82.5 g_

Hence, the mass of copper electrode after 10.0 h is 82.5 g_ .

Similarly, the equivalent weight of zinc is calculated by using the given expression,

Equivalent weight=Atomic weightValancy .

The atomic weight of zinc is 65.41 amu .

Substitute the value of atomic weight and valancy of zinc in the above expression to calculate its equivalent weight,

Equivalent weight=Atomic weightValancy=65.412=32.705

Hence, electrochemical equivalent (Z) is calculated as,

Z=Equivalent weightF=32.70596485=3.38×104 .

The weight of zinc deposited is calculated by using the given expression,

W=Z×c×t .

Where,

  • Z is the electrochemical equivalent.
  • c is the charge.
  • t is the time in sec.

Substitute the value of Z , c and t in the above expression to calculate the weight of zinc deposited.

W=Z×c×t=3.38×104×10×3600=121.68 g

If the weight of zinc deposited in 10 hr is 121.68 g . Then the weight of zinc electrode after 10 hr is calculated as,

Weight of Zn electrode=Total mass of electrodeWeight of Zn in 10hr=200121.68=78.32 g_

Hence, the mass of zinc electrode after 10.0 h is 78.32 g_ .

(d)

Interpretation Introduction

Interpretation: The cell potential Ecell of the given cell, the mass of each electrode after 10.0 h and the time of the given battery to deliver a current of 10.0 A before it goes dead is to be calculated.

Concept introduction: Cell potential is defined as the measure of energy per unit charge available from the redox reaction to carry out the reaction. The electrochemical equivalent is defined as the mass of the element transported when electricity of one coulomb charge is passed.

To determine: The time of the given battery to deliver a current of 10.0 A before it goes dead.

(d)

Expert Solution
Check Mark

Answer to Problem 144CP

Answer

The time of the given battery to deliver a current of 10.0 A before it goes dead is 17.36 hr_ .

Explanation of Solution

Explanation

Given

The battery delivers current till all the copper is deposited

The weight of copper to be deposited is W=200 g .

Current (C) is 10.0 A .

Electrochemical equivalent of copper (Z)=3.2×104 .

The time is calculated by using the expression,

W=Z×c×tt=WZ×c

Substitute the value of W, Z and c in the above expression to calculate the time of the given battery.

t=WZ×ct=2003.2×104×10=62.5×103 sec

The conversion of sec to hr is done as,

1 sec=160 min= 13600hr

Therefore, the conversion of 62.5×103 sec to hr is done as,

1 sec=160 min= 13600hr62.5×103 sec=62.5×1033600hr=17.36 hr_

Hence, the time of the given battery to deliver a current of 10.0 A before it goes dead is 17.36 hr_ .

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Chapter 17 Solutions

Chemistry: An Atoms First Approach

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