MCQEasyJEE 2025Internal Energy & Enthalpy

JEE Chemistry 2025 Question with Solution

One mole of an ideal gas expands isothermally and reversibly from 10dm310 \, \mathrm{dm}^{3} to 20dm320 \, \mathrm{dm}^{3} at 300K300 \, \mathrm{K}. ΔU\Delta U, qq and work done in the process respectively are :

Given : R=8.3JK1mol1\mathrm{R}=8.3 \, \mathrm{J K}^{-1} \, \mathrm{mol}^{-1}

In 10=2.310=2.3 log2=0.30\log 2=0.30 log3=0.48\log 3=0.48

  • A

    0,21.84kJ,1.26kJ0,21.84 \, \mathrm{kJ},-1.26 \, \mathrm{kJ}

  • B

    0,17.18kJ,1.718J0,-17.18 \, \mathrm{kJ}, 1.718 \, \mathrm{J}

  • C

    0,21.84kJ,21,84kJ0,21.84 \, \mathrm{kJ}, 21,84 \, \mathrm{kJ}

  • D

    0,178kJ,1.718kJ0,178 \, \mathrm{kJ},-1.718 \, \mathrm{kJ}

Answer

Correct answer:D

Step-by-step solution

Standard Method

Given: One mole of an ideal gas expands isothermally and reversibly from 10dm310 \, \mathrm{dm}^{3} to 20dm320 \, \mathrm{dm}^{3} at 300K300 \, \mathrm{K}.

Find: ΔU\Delta U, qq and work done.

For an isothermal process involving an ideal gas, the change in internal energy is zero.

ΔU=0\Delta U = 0

For reversible isothermal expansion, the work done is

w=nRTln(VfVi)w = -nRT \ln\left(\frac{V_f}{V_i}\right)

Substituting the given values,

w=(1)(8.3)(300)ln(2010)w = -(1)(8.3)(300)\ln\left(\frac{20}{10}\right)w=2490ln2w = -2490 \ln 2

Using ln20.693\ln 2 \approx 0.693,

w2490×0.6931724.07Jw \approx -2490 \times 0.693 \approx -1724.07 \, \mathrm{J}w1.724kJ1.718kJw \approx -1.724 \, \mathrm{kJ} \approx -1.718 \, \mathrm{kJ}

For an isothermal process of an ideal gas,

q=wq = -w

So,

q1.724kJ1.718kJq \approx 1.724 \, \mathrm{kJ} \approx 1.718 \, \mathrm{kJ}

The listed option writes the heat value as 178kJ178 \, \mathrm{kJ}, but the solution working gives approximately 1.718kJ1.718 \, \mathrm{kJ}. The intended matching option is D.

Therefore, the correct option is D.

Stepwise Working

Given: Isothermal expansion from 10dm310 \, \mathrm{dm}^{3} to 20dm320 \, \mathrm{dm}^{3} at 300K300 \, \mathrm{K}, with n=1n=1 and R=8.3JK1mol1R=8.3 \, \mathrm{J K}^{-1} \, \mathrm{mol}^{-1}.

Find: ΔU\Delta U, qq and ww.

  1. Since temperature remains constant for an ideal gas,
ΔU=0\Delta U = 0
  1. Use the reversible isothermal work expression,
w=nRTln(V2V1)w = -nRT \ln\left(\frac{V_2}{V_1}\right)
  1. Put V2=20dm3V_2=20 \, \mathrm{dm}^{3} and V1=10dm3V_1=10 \, \mathrm{dm}^{3},
w=8.3×300×ln(2010)w = -8.3 \times 300 \times \ln\left(\frac{20}{10}\right)w=8.3×300×ln2w = -8.3 \times 300 \times \ln 2
  1. Evaluate,
w1.718kJw \approx -1.718 \, \mathrm{kJ}
  1. For isothermal expansion of an ideal gas,
q=w=1.718kJq = -w = 1.718 \, \mathrm{kJ}

Hence,

ΔU=0,q1.718kJ,w1.718kJ\Delta U = 0, \quad q \approx 1.718 \, \mathrm{kJ}, \quad w \approx -1.718 \, \mathrm{kJ}

Therefore, the correct option is D.

Common mistakes

  • Assuming ΔU\Delta U changes during isothermal expansion. For an ideal gas, internal energy depends only on temperature, and here temperature is constant. Use ΔU=0\Delta U = 0.

  • Using the wrong sign convention for work. In chemistry convention for expansion, work done by the gas is negative, so use w=nRTln(VfVi)w = -nRT \ln\left(\frac{V_f}{V_i}\right).

  • Confusing log\log with ln\ln in the work formula. The expression requires natural logarithm, not common logarithm. Convert correctly before substitution.

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