Chapter 18, Problem 18.64QE

a)

Interpretation Introduction

Interpretation:

$E^{°}{}_{cell}$ for the given voltaic cell has to be determined.

  $\text{ 2}{\text{Ag}}^{\text{+}}\text{(aq) +Cd}\text{(s) }\to \text{ 2}\text{Ag}{\text{(s) + Cd}}^{+2}\text{(aq)}$

Concept Introduction:

Electrochemical cells:

In all electrochemical cells, oxidation occurs at anode and reduction occurs at cathode.

An anode is indicated by negative sign and cathode is indicated by the positive sign.

Electrons flow in the external circuit from the anode to the cathode.

In the electrochemical cells two half cells are connected with salt bridge. It allows the cations and anions to move between the two half cells.

Standard potential ${\text{(E}}_{\text{cell}}^{\text{o}}\text{)}$ can be calculated by the following formula.

  ${\text{E}}_{\text{cell}}^{\text{o}}{\text{=E}}_{\text{cathode}}^{\text{o}}{\text{-E}}_{\text{anode}}^{\text{o}}$

If ${\text{E}}_{\text{cell}}^{\text{o}}$ value is positive, then the reaction is predicted to be spontaneous at that direction.

If ${\text{E}}_{\text{cell}}^{\text{o}}$ value is negative, then the reaction is predicted to be spontaneous at reverse direction.

The relation between standard cell potential and equilibrium constant is as follows.

  $\text{log}\text{K = }\frac{{\text{nE}}^{\text{0}}}{\text{0}\text{.0591}}\text{ at 298K}$

b)

Interpretation Introduction

Interpretation:

$E^{}{}_{cell}$ for the given voltaic cell has to be determined if the concentration of ${\text{Cd}}^{\text{+2}}\text{is}\text{2}\text{.0}\text{M}\text{and}{\text{Ag}}^{\text{+}}\text{is}\text{0}\text{.25}\text{M}$.

  $\text{ 2}{\text{Ag}}^{\text{+}}\text{(aq) +Cd}\text{(s) }\to \text{ 2}\text{Ag}{\text{(s) + Cd}}^{+2}\text{(aq)}$

Concept Introduction:

Refer to (a)

c)

Interpretation Introduction

Interpretation:

The concentration of silver ion has to be determined if the $E^{°}{}_{cell}$ for the given voltaic cell is $1.25V$ and the concentration of ${\text{Cd}}^{\text{+2}}\text{is}0.100\text{M}$.

  $\text{ 2}{\text{Ag}}^{\text{+}}\text{(aq) +Cd}\text{(s) }\to \text{ 2}\text{Ag}{\text{(s) + Cd}}^{+2}\text{(aq)}$

Concept Introduction:

Refer to (a).