(a) Interpretation: Balanced equation for each cell reaction should be written. Concept introduction: A galvanic cell can be represented using a shorthand notation. For example, a redox reaction and its cell notation is given below. Zn(s) + Cu 2 + (aq) → Zn 2 + (aq) + Cu(s) Zn(s) | Zn 2 + (aq) || Cu 2 + (aq) | Cu(s) The single vertical line (|) indicates the phase boundary. The double vertical line (||) indicates the salt bridge. The shorthand notation for anode half-cell is written on left side of the double vertical line and notation for cathode half-cell is written on the right side of the double vertical line. The electrodes are indicated in the two extreme ends of the cell notation. Always reactants in each half-cell is written first and followed by products. The electrons move through the external circuit from left to right (from anode to cathode).

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Answer 1

Question

Chapter 19, Problem 19.37CP

Interpretation Introduction

(a)

Interpretation:

Balanced equation for each cell reaction should be written.

Concept introduction:

A galvanic cell can be represented using a shorthand notation. For example, a redox reaction and its cell notation is given below.

Zn(s) + Cu2+(aq) → Zn2+(aq) + Cu(s)

Zn(s) | Zn2+(aq) || Cu2+(aq) | Cu(s)

The single vertical line (|) indicates the phase boundary. The double vertical line (||) indicates the salt bridge. The shorthand notation for anode half-cell is written on left side of the double vertical line and notation for cathode half-cell is written on the right side of the double vertical line. The electrodes are indicated in the two extreme ends of the cell notation. Always reactants in each half-cell is written first and followed by products. The electrons move through the external circuit from left to right (from anode to cathode).

Interpretation Introduction

(b)

Interpretation:

Each cell should be sketched and anode and cathode should be labeled. The direction of electron and ion flow should be indicated.

Concept introduction:

Anode is the electrode where oxidation takes place and electrons are produced. Anode has a negative sign in galvanic cell. Cathode is the electrode where reduction takes place and electrons are consumed. Cathode has a positive sign.

Anions move form cathode compartment towards anode compartment while cations migrate from the anode compartment towards the cathode compartment.

Interpretation Introduction

(c)

Interpretation:

Which cell has the largest and which has the smallest cell potential should be deduced.

Concept introduction:

The Nernst equation allows to calculate cell potential at non-standard conditions.

E=E0−0.0592 VnlogQ

E − non-standard cell potential

E⁰ − standard cell potential

n − number of electrons passed through the cell

Q − reaction quotient

The standard cell potential of overall reaction is given by the sum of the standard half-cell potentials for oxidation and reduction.

Eoverall0=Eox0+ Ered0

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Answer 2

Question

Chapter 19, Problem 19.37CP

Interpretation Introduction

(a)

Interpretation:

Balanced equation for each cell reaction should be written.

Concept introduction:

A galvanic cell can be represented using a shorthand notation. For example, a redox reaction and its cell notation is given below.

Zn(s) + Cu2+(aq) → Zn2+(aq) + Cu(s)

Zn(s) | Zn2+(aq) || Cu2+(aq) | Cu(s)

The single vertical line (|) indicates the phase boundary. The double vertical line (||) indicates the salt bridge. The shorthand notation for anode half-cell is written on left side of the double vertical line and notation for cathode half-cell is written on the right side of the double vertical line. The electrodes are indicated in the two extreme ends of the cell notation. Always reactants in each half-cell is written first and followed by products. The electrons move through the external circuit from left to right (from anode to cathode).

Interpretation Introduction

(b)

Interpretation:

Each cell should be sketched and anode and cathode should be labeled. The direction of electron and ion flow should be indicated.

Concept introduction:

Anode is the electrode where oxidation takes place and electrons are produced. Anode has a negative sign in galvanic cell. Cathode is the electrode where reduction takes place and electrons are consumed. Cathode has a positive sign.

Anions move form cathode compartment towards anode compartment while cations migrate from the anode compartment towards the cathode compartment.

Interpretation Introduction

(c)

Interpretation:

Which cell has the largest and which has the smallest cell potential should be deduced.

Concept introduction:

The Nernst equation allows to calculate cell potential at non-standard conditions.

E=E0−0.0592 VnlogQ

E − non-standard cell potential

E⁰ − standard cell potential

n − number of electrons passed through the cell

Q − reaction quotient

The standard cell potential of overall reaction is given by the sum of the standard half-cell potentials for oxidation and reduction.

Eoverall0=Eox0+ Ered0

Expert Solution & Answer

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See solution

Answer 3

Question

Chapter 19, Problem 19.37CP

Interpretation Introduction

(a)

Interpretation:

Balanced equation for each cell reaction should be written.

Concept introduction:

A galvanic cell can be represented using a shorthand notation. For example, a redox reaction and its cell notation is given below.

Zn(s) + Cu2+(aq) → Zn2+(aq) + Cu(s)

Zn(s) | Zn2+(aq) || Cu2+(aq) | Cu(s)

The single vertical line (|) indicates the phase boundary. The double vertical line (||) indicates the salt bridge. The shorthand notation for anode half-cell is written on left side of the double vertical line and notation for cathode half-cell is written on the right side of the double vertical line. The electrodes are indicated in the two extreme ends of the cell notation. Always reactants in each half-cell is written first and followed by products. The electrons move through the external circuit from left to right (from anode to cathode).

Interpretation Introduction

(b)

Interpretation:

Each cell should be sketched and anode and cathode should be labeled. The direction of electron and ion flow should be indicated.

Concept introduction:

Anode is the electrode where oxidation takes place and electrons are produced. Anode has a negative sign in galvanic cell. Cathode is the electrode where reduction takes place and electrons are consumed. Cathode has a positive sign.

Anions move form cathode compartment towards anode compartment while cations migrate from the anode compartment towards the cathode compartment.

Interpretation Introduction

(c)

Interpretation:

Which cell has the largest and which has the smallest cell potential should be deduced.

Concept introduction:

The Nernst equation allows to calculate cell potential at non-standard conditions.

E=E0−0.0592 VnlogQ

E − non-standard cell potential

E⁰ − standard cell potential

n − number of electrons passed through the cell

Q − reaction quotient

The standard cell potential of overall reaction is given by the sum of the standard half-cell potentials for oxidation and reduction.

Eoverall0=Eox0+ Ered0

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Answer 4

Question

Chapter 19, Problem 19.37CP

Interpretation Introduction

(a)

Interpretation:

Balanced equation for each cell reaction should be written.

Concept introduction:

A galvanic cell can be represented using a shorthand notation. For example, a redox reaction and its cell notation is given below.

Zn(s) + Cu2+(aq) → Zn2+(aq) + Cu(s)

Zn(s) | Zn2+(aq) || Cu2+(aq) | Cu(s)

The single vertical line (|) indicates the phase boundary. The double vertical line (||) indicates the salt bridge. The shorthand notation for anode half-cell is written on left side of the double vertical line and notation for cathode half-cell is written on the right side of the double vertical line. The electrodes are indicated in the two extreme ends of the cell notation. Always reactants in each half-cell is written first and followed by products. The electrons move through the external circuit from left to right (from anode to cathode).

Interpretation Introduction

(b)

Interpretation:

Each cell should be sketched and anode and cathode should be labeled. The direction of electron and ion flow should be indicated.

Concept introduction:

Anode is the electrode where oxidation takes place and electrons are produced. Anode has a negative sign in galvanic cell. Cathode is the electrode where reduction takes place and electrons are consumed. Cathode has a positive sign.

Anions move form cathode compartment towards anode compartment while cations migrate from the anode compartment towards the cathode compartment.

Interpretation Introduction

(c)

Interpretation:

Which cell has the largest and which has the smallest cell potential should be deduced.

Concept introduction:

The Nernst equation allows to calculate cell potential at non-standard conditions.

E=E0−0.0592 VnlogQ

E − non-standard cell potential

E⁰ − standard cell potential

n − number of electrons passed through the cell

Q − reaction quotient

The standard cell potential of overall reaction is given by the sum of the standard half-cell potentials for oxidation and reduction.

Eoverall0=Eox0+ Ered0

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Answer 5

Chapter 19, Problem 19.37CP

Interpretation Introduction

(a)

Interpretation:

Balanced equation for each cell reaction should be written.

Concept introduction:

A galvanic cell can be represented using a shorthand notation. For example, a redox reaction and its cell notation is given below.

Zn(s) + Cu2+(aq) → Zn2+(aq) + Cu(s)

Zn(s) | Zn2+(aq) || Cu2+(aq) | Cu(s)

The single vertical line (|) indicates the phase boundary. The double vertical line (||) indicates the salt bridge. The shorthand notation for anode half-cell is written on left side of the double vertical line and notation for cathode half-cell is written on the right side of the double vertical line. The electrodes are indicated in the two extreme ends of the cell notation. Always reactants in each half-cell is written first and followed by products. The electrons move through the external circuit from left to right (from anode to cathode).

Interpretation Introduction

(b)

Interpretation:

Each cell should be sketched and anode and cathode should be labeled. The direction of electron and ion flow should be indicated.

Concept introduction:

Anode is the electrode where oxidation takes place and electrons are produced. Anode has a negative sign in galvanic cell. Cathode is the electrode where reduction takes place and electrons are consumed. Cathode has a positive sign.

Anions move form cathode compartment towards anode compartment while cations migrate from the anode compartment towards the cathode compartment.

Interpretation Introduction

(c)

Interpretation:

Which cell has the largest and which has the smallest cell potential should be deduced.

Concept introduction:

The Nernst equation allows to calculate cell potential at non-standard conditions.

E=E0−0.0592 VnlogQ

E − non-standard cell potential

E⁰ − standard cell potential

n − number of electrons passed through the cell

Q − reaction quotient

The standard cell potential of overall reaction is given by the sum of the standard half-cell potentials for oxidation and reduction.

Eoverall0=Eox0+ Ered0

Answer 6

Chapter 19, Problem 19.37CP

Interpretation Introduction

(a)

Interpretation:

Balanced equation for each cell reaction should be written.

Concept introduction:

A galvanic cell can be represented using a shorthand notation. For example, a redox reaction and its cell notation is given below.

Zn(s) + Cu2+(aq) → Zn2+(aq) + Cu(s)

Zn(s) | Zn2+(aq) || Cu2+(aq) | Cu(s)

The single vertical line (|) indicates the phase boundary. The double vertical line (||) indicates the salt bridge. The shorthand notation for anode half-cell is written on left side of the double vertical line and notation for cathode half-cell is written on the right side of the double vertical line. The electrodes are indicated in the two extreme ends of the cell notation. Always reactants in each half-cell is written first and followed by products. The electrons move through the external circuit from left to right (from anode to cathode).

Answer 7

Chapter 19, Problem 19.37CP

Interpretation Introduction

(a)

Interpretation:

Balanced equation for each cell reaction should be written.

Concept introduction:

A galvanic cell can be represented using a shorthand notation. For example, a redox reaction and its cell notation is given below.

Zn(s) + Cu2+(aq) → Zn2+(aq) + Cu(s)

Zn(s) | Zn2+(aq) || Cu2+(aq) | Cu(s)

The single vertical line (|) indicates the phase boundary. The double vertical line (||) indicates the salt bridge. The shorthand notation for anode half-cell is written on left side of the double vertical line and notation for cathode half-cell is written on the right side of the double vertical line. The electrodes are indicated in the two extreme ends of the cell notation. Always reactants in each half-cell is written first and followed by products. The electrons move through the external circuit from left to right (from anode to cathode).

Answer 8

Interpretation Introduction

(b)

Interpretation:

Each cell should be sketched and anode and cathode should be labeled. The direction of electron and ion flow should be indicated.

Concept introduction:

Anode is the electrode where oxidation takes place and electrons are produced. Anode has a negative sign in galvanic cell. Cathode is the electrode where reduction takes place and electrons are consumed. Cathode has a positive sign.

Anions move form cathode compartment towards anode compartment while cations migrate from the anode compartment towards the cathode compartment.

Answer 9

Interpretation Introduction

(b)

Interpretation:

Each cell should be sketched and anode and cathode should be labeled. The direction of electron and ion flow should be indicated.

Concept introduction:

Anode is the electrode where oxidation takes place and electrons are produced. Anode has a negative sign in galvanic cell. Cathode is the electrode where reduction takes place and electrons are consumed. Cathode has a positive sign.

Anions move form cathode compartment towards anode compartment while cations migrate from the anode compartment towards the cathode compartment.

Answer 10

Interpretation Introduction

(c)

Interpretation:

Which cell has the largest and which has the smallest cell potential should be deduced.

Concept introduction:

The Nernst equation allows to calculate cell potential at non-standard conditions.

E=E0−0.0592 VnlogQ

E − non-standard cell potential

E⁰ − standard cell potential

n − number of electrons passed through the cell

Q − reaction quotient

The standard cell potential of overall reaction is given by the sum of the standard half-cell potentials for oxidation and reduction.

Eoverall0=Eox0+ Ered0

Answer 11

Interpretation Introduction

(c)

Interpretation:

Which cell has the largest and which has the smallest cell potential should be deduced.

Concept introduction:

The Nernst equation allows to calculate cell potential at non-standard conditions.

E=E0−0.0592 VnlogQ

E − non-standard cell potential

E⁰ − standard cell potential

n − number of electrons passed through the cell

Q − reaction quotient

The standard cell potential of overall reaction is given by the sum of the standard half-cell potentials for oxidation and reduction.

Eoverall0=Eox0+ Ered0

Answer 12

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Answer 13

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Answer 14

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Answer 15

Ch. 19 - Balance the following net ionic equation by the...Ch. 19 - Balance the following net ionic equation by the...Ch. 19 - Prob. 19.3P Ch. 19 - Balance the following net ionic equation by the...Ch. 19 - Prob. 19.5P Ch. 19 - Prob. 19.6A Ch. 19 - PRACTICE 18.7 Write a balanced equation for the...Ch. 19 - Consider the following galvanic cell with...Ch. 19 - The standard cell potential at 25oC is 1.20 V for...Ch. 19 - The standard free-energy change is 59.8kJ for the...

Solution Summary: The author illustrates how a galvanic cell can be represented using shorthand notation.

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Chapter 19 Solutions