MCQEasyJEE 2024Cells, EMF & Internal Resistance

JEE Physics 2024 Question with Solution

Two cells are connected in opposition. Cell E1E_1 has 8V8 \, \text{V} emf and 2Ω2 \, \Omega internal resistance. Cell E2E_2 has 2V2 \, \text{V} emf and 4Ω4 \, \Omega internal resistance. The terminal potential difference of cell E2E_2 is:

  • A

    7V7 \, \text{V}

  • B

    15V15 \, \text{V}

  • C

    44V44 \, \text{V}

  • D

    22V22 \, \text{V}

Answer

Correct answer:A

Step-by-step solution

Standard Method

Given: Cell E1=8VE_1 = 8 \, \text{V}, r1=2Ωr_1 = 2 \, \Omega; cell E2=2VE_2 = 2 \, \text{V}, r2=4Ωr_2 = 4 \, \Omega. The cells are connected in opposition.

Find: The terminal potential difference of cell E2E_2.

Since the cells are connected in opposition, the net emf is

Enet=E1E2=82=6VE_{\text{net}} = E_1 - E_2 = 8 - 2 = 6 \, \text{V}

The total internal resistance is

Rtotal=r1+r2=2+4=6ΩR_{\text{total}} = r_1 + r_2 = 2 + 4 = 6 \, \Omega

Hence the current in the circuit is

I=EnetRtotal=66=1AI = \frac{E_{\text{net}}}{R_{\text{total}}} = \frac{6}{6} = 1 \, \text{A}

Because E1>E2E_1 > E_2, cell E2E_2 is being charged. Therefore its terminal potential difference is

VT2=E2+Ir2V_{T2} = E_2 + I r_2

Substituting the values,

VT2=2+(1)(4)=6VV_{T2} = 2 + (1)(4) = 6 \, \text{V}

Therefore, the terminal potential difference of cell E2E_2 is 6V6 \, \text{V}.

The solution gives 6V6 \, \text{V}, but this value is not present in the listed options. The answer key key marks option A. Since the source options and solution are inconsistent, the most defensible recorded answer is A with this discrepancy noted.

Common mistakes

  • Using the emfs in the same direction and taking Enet=E1+E2E_{\text{net}} = E_1 + E_2. This is wrong because the cells are connected in opposition. Use the difference of emfs, with current driven by the larger emf.

  • Using V=EIrV = E - Ir for cell E2E_2. This is wrong because cell E2E_2 is being charged, so current enters its positive terminal. For a charging cell, use V=E+IrV = E + Ir.

  • Ignoring internal resistances while finding current. This is wrong because the loop current depends on the total internal resistance of both cells. First add r1r_1 and r2r_2, then apply Ohm's law for the complete circuit.

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