250+ TOP MCQs on Electrochemistry – Nernst Equation and Answers

Chemistry Multiple Choice Questions on “Electrochemistry – Nernst Equation”.

1. The standard oxidation potential of Ni/Ni²⁺ electrode is 0.3 V. If this is combined with a hydrogen electrode in acid solution, at what pH of the solution with the measured e.m.f. be zero at 25°C? (Assume [Ni²⁺] = 1M)
a) 5.08
b) 4
c) 4.5
d) 5.25
Answer: a
Clarification: Given,
Standard oxidation potential of Ni/Ni²⁺ electrode, E°_OP = 0.3 V,
Ni → Ni²⁺ + 2e
2H⁺ + 2e → H₂
E°_cell = E° _(OP) + E° _(RP)
E° _(cell) = 0.3 + 0.0 = 0.3 V
According to Nernst equation, E (cell) = E°_(cell) + (frac{0.059}{2}) log₁₀([H⁺]² / [Ni]⁺²)
0 = 0.3 + (frac{0.059}{2})log₁₀([H⁺]²)
-log ([H⁺]) = 5.08
pH = 5.08.

2. Calculate the equilibrium constant for the reaction Fe + CuSO₄ ⇌ FeSO₄ + Cu at 25°C.
(Given E°(OP/Fe) = 0.5 V°, E°(OP/Cu) = -0.4 V)
a) 3.46 × 10³⁰
b) 3.46 × 10²⁶
c) 3.22 × 10³⁰
d) 3.22 × 10²⁶
Answer: c
Clarification: The cell reaction shows oxidation of Fe and reduction of Cu²⁺
Therefore for the reaction, Fe + CuSO₄ ⇌ FeSO₄ + Cu
E°_(cell) = E°_(OP/Fe) + E°_(RP/Cu)
E°_(cell) = 0.5 + 0.4 = 0.9 V
We have, E° = (frac{0.059}{2})log₁₀ K_c
0.9 = (frac{0.059}{2})log₁₀ K_c
K_c = 3.22 × 10³⁰.

3. Calculate the e.m.f. of the half-cell given below.
Pt, H₂ | HCl at 1-atmosphere pressure and 0.1 M. Given, E°_(OP) = 2 V.
a) 4 V
b) 5.6 V
c) 3.4 V
d) 5.4 V
Answer: d
Clarification: Given, E°_(OP) = 2 V,
H₂ → 2H⁺ + 2e
E_(OP) = E°_(OP) – (frac{0.059}{2})log₁₀([H⁺]²/ P (H₂))
E_(OP) = 2 – (frac{0.059}{2})log₁₀ (0.02² / 1) = 5.4 V.

4. The equilibrium constant for a cell reaction, Cu_(g) + 2Ag⁺_(aq) → Cu²⁺_(aq) + 2Ag _(s) is 4 × 10¹⁶. Find E° _(cell) for the cell reaction.
a) 0.63 V
b) 0.49 V
c) 1.23 V
d) 3.24 V
Answer: b
Clarification: Given, equilibrium constant K_c = 4 × 10¹⁶
E° _(cell) = (frac{0.059}{2})log₁₀ K_c
E°_(cell) = (frac{0.059}{2})log₁₀ (4 × 10¹⁶)=0.49V.

5. What is the correct Nernst equation for M²⁺ (aq) + 2e⁺ → M (s) at 45°C?
a) E°_(M2+/M) + 0.315log₁₀ (1 / [M]⁺²)
b) E° _(M2+/M) + 0.0425log₁₀ (1 / [M]⁺²)
c) E° _(M2+/M) + 0.0315log₁₀ (1 / [M]⁺²)
d) E° _(M2+/M) + 0.0326log₁₀ (1 / [M]⁺²)
Answer: c
Clarification: Given, Temperature T = 45°C
We know, n (number of electrons transferred) = 2
According to Nernst equation, E_(M2+/M) = E° _(M2+/M) +2.303(frac{RT}{nF})log₁₀ (M / [M]⁺²)
Concentration of [M] is taken to be 1
The equation becomes: E° _(M2+/M) +2.303 (frac{RT}{nF})log₁₀ (1/[M]⁺²)
E_(M2+/M) = E° _(M2+/M) +2.303 × (frac{8.314 times 318}{2 times 96500})log₁₀ (1 / [M]⁺²) =E° _(M2+/M) + 0.0315log₁₀ (1 / [M]⁺²).

6. The e.m.f and the standard e.m.f of a cell in the following reaction is 5 V and 5.06 V at room temperature, Ni_(s) + 2Ag⁺_(n) → Ni²⁺_(0.02M) + 2Ag_(s). What is the concentration of Ag⁺ ions?
a) 0.0125 M
b) 0.0314 M
c) 0.0625 M
d) 0.0174 M
Answer: d
Clarification: Given, Temperature T = 298K
Concentration of Ni²⁺ = (0.02M)
E_(cell) = E°_(cell) – (frac{0.059}{n})log₁₀ (Anode / Cathode)
5 = 5.06 – (frac{0.059}{2})log₁₀(0.02 / [Ag⁺]²)
[Ag⁺]² = 0.0174 M.

7. Calculate the electrode potential of the given electrode.
Pt, Cl_{2(2 bar)}| 2Cl^–_{(0.02 M)}; E°_{(Cl2 | 2Cl^–)} = 3.4 V
a) 3.51 V
b) 3.55 V
c) 1.26 V
d) 2.95 V
Answer: a
Clarification: The electrode reaction is Cl_2(g) + 2e^– → 2Cl^–
E = E˚ – (frac{0.059}{n})log ([Cl^–]² / P_(Cl₂))
E = 3.4 – (frac{0.059}{2})log (0.02² / 2) = 3.51 V.

8. A zinc rod dipped in n molar solution of ZnSO₄ has an electrode potential of -0.56 V. The salt is 98 percent dissociated at room temperature. What is the molarity of the solution? (E°_(Zn+2/Zn) = -0.5 V)
a) 8.44 × 10^-3 M
b) 9.44 × 10^-4 M
c) 8.44 × 10^-4 M
d) 9.44 × 10^-3 M
Answer: d
Clarification: The electrode reaction is Zn²⁺ + 2e^– → Zn
The number of electrons transferred, n= 2
Applying Nernst equation, we get E_(Zn+2/Zn) = E°_(Zn+2/Zn) – (frac{0.059}{2})log (1 / [Zn²⁺])
[Zn²⁺] = (frac{98}{100}) × n = 0.98n M
-0.56 = -0.5 – (frac{0.059}{2})log (1 / 0.98n)
n= 9.44 × 10^-3 M.

9. What is the pH of HCl solution when the hydrogen gas electrode shows a potential of -0.22 V at standard temperature and pressure?
a) 2.17
b) 2.98
c) 3.73
d) 3.14
Answer: c
Clarification: Given, potential of hydrogen gas electrode = -0.22 V
Electrode reaction: H⁺ + e^– → 0.5 H₂
Applying Nernst equation,
E_(H+/H₂) = E°(H+/H₂) – 0.059 log (1/ [H⁺])
E°_(H+/H₂) = 0 for hydrogen gas electrode
-0.22 = 0.059 log H⁺
-0.22 = -0.059pH
pH= 3.73.

10. What is the value of universal gas constant in Nernst equation when the potential is given in volts?
a) 8.314 J mol^-1K^-1
b) 0.0821 L atm mol^-1K^-1
c) 8.205 m³ atm mol^-1K^-1
d) 1.987 cal mol^-1K^-1
Answer: a
Clarification: The universal gas constant is denoted by R and is expressed in units of energy per temperature per mole. Since volts is the SI-Unit of potential, R must also be taken in SI-Units which is J mol^-1K^-1.

11. What is the number of electrons transferred in an equation if the Nernst equation is E_(cell) = E°_(cell) – 9.83 × 10^-3 × log₁₀ (Anode / Cathode)?
a) 2
b) 6
c) 4
d) 1
Answer: b
Clarification: Nernst equation = E°_(cell) – (frac{0.059}{n}) log₁₀(Anode / Cathode)
On comparing both the formulae, (frac{0.059}{n}) = 9.83 × 10^-3
n= 6.

12. Find the number of electrons transferred in the equation Cu_(g) + 2Ag⁺_(aq) → Cu²⁺_(aq) + 2Ag_(s).
a) 4
b) 3
c) 2
d) 1
Answer: c
Clarification: 2Ag⁺_(aq) + 2e^– → 2Ag_(s)
From the equation it is evident that 2Ag⁺ takes 2 electrons from Cu and neutralizes to form 2Ag.