MCQMediumJEE 2025Potential Energy & Conservative Forces

JEE Physics 2025 Question with Solution

Two cylindrical vessels of equal cross-sectional area of 2m22 \, \text{m}^2 contain water up to heights 10m10 \, \text{m} and 6m6 \, \text{m}, respectively. If the vessels are connected at their bottom, then the work done by the force of gravity is: (Density of water is 103kg/m310^3 \, \text{kg/m}^3 and g=10m/s2g = 10 \, \text{m/s}^2)

  • A

    1×105J1 \times 10^5 \, \text{J}

  • B

    4×104J4 \times 10^4 \, \text{J}

  • C

    6×104J6 \times 10^4 \, \text{J}

  • D

    8×104J8 \times 10^4 \, \text{J}

Answer

Correct answer:D

Step-by-step solution

Standard Method

Given: Two cylindrical vessels each have cross-sectional area A=2m2A = 2 \, \text{m}^2. The initial water heights are h1=10mh_1 = 10 \, \text{m} and h2=6mh_2 = 6 \, \text{m}. The density of water is ρ=103kg/m3\rho = 10^3 \, \text{kg/m}^3 and acceleration due to gravity is g=10m/s2g = 10 \, \text{m/s}^2.

Find: The work done by the force of gravity when the vessels are connected at the bottom.

When the vessels are connected, the water levels become equal. Using conservation of volume,

Vi=Ah1+Ah2=2(10)+2(6)=32m3V_i = Ah_1 + Ah_2 = 2(10) + 2(6) = 32 \, \text{m}^3

Since both vessels have the same area, the final common height hfh_f satisfies

2Ahf=322A h_f = 32

With A=2m2A = 2 \, \text{m}^2,

4hf=324h_f = 32

so

hf=8mh_f = 8 \, \text{m}

The work done by gravity equals the loss in gravitational potential energy.

For the water in the first vessel:

m1=ρAh1=103×2×10=20000kgm_1 = \rho A h_1 = 10^3 \times 2 \times 10 = 20000 \, \text{kg}

Its center of mass falls by

h1hf2=1082=1m\frac{h_1 - h_f}{2} = \frac{10 - 8}{2} = 1 \, \text{m}

Hence,

ΔU1=m1g×1=20000×10=200000J\Delta U_1 = m_1 g \times 1 = 20000 \times 10 = 200000 \, \text{J}

For the water in the second vessel:

m2=ρAh2=103×2×6=12000kgm_2 = \rho A h_2 = 10^3 \times 2 \times 6 = 12000 \, \text{kg}

Its center of mass rises by

hfh22=862=1m\frac{h_f - h_2}{2} = \frac{8 - 6}{2} = 1 \, \text{m}

Hence,

ΔU2=m2g×1=12000×10=120000J\Delta U_2 = m_2 g \times 1 = 12000 \times 10 = 120000 \, \text{J}

Therefore, the net work done by gravity is

W=ΔU1ΔU2=200000120000=80000JW = \Delta U_1 - \Delta U_2 = 200000 - 120000 = 80000 \, \text{J}

Thus, the work done by gravity is 8×104J8 \times 10^4 \, \text{J}. The correct option is D.

Potential Energy Difference Method

Given: The two vessels have equal area A=2m2A = 2 \, \text{m}^2 with initial heights 10m10 \, \text{m} and 6m6 \, \text{m}.

Find: The work done by gravity.

Compute the initial potential energy directly using center of mass of each water column:

Ui=(ρA×10)g×5+(ρA×6)g×3U_i = (\rho A \times 10)g \times 5 + (\rho A \times 6)g \times 3 Ui=ρAg(50+18)=68ρAgU_i = \rho A g (50 + 18) = 68\rho A g

The total height after equalization is

10+6=1610 + 6 = 16

so the final height in each vessel is

hf=8mh_f = 8 \, \text{m}

The final potential energy is

Uf=(ρA×16)g×4=64ρAgU_f = (\rho A \times 16)g \times 4 = 64\rho A g

Hence the work done by gravity is the decrease in potential energy:

W=UiUf=(6864)ρAg=4ρAgW = U_i - U_f = (68 - 64)\rho A g = 4\rho A g

Substituting values,

W=4×1000×2×10=8×104JW = 4 \times 1000 \times 2 \times 10 = 8 \times 10^4 \, \text{J}

Therefore, the work done by gravity is 8×104J8 \times 10^4 \, \text{J}.

Common mistakes

  • Using pressure difference formulas instead of energy conservation is incorrect here because the question asks for work done by gravity. First find the final common height by volume conservation, then evaluate the change in gravitational potential energy.

  • Taking the final height as 16m16 \, \text{m} or 8/2m8/2 \, \text{m} is wrong. The total volume is shared between two vessels of equal area, so the correct final height is obtained from 2Ahf=A(10)+A(6)2A h_f = A(10) + A(6), giving hf=8mh_f = 8 \, \text{m}.

  • Using the full height change of the liquid columns instead of the center-of-mass shift gives an incorrect energy change. For a uniform liquid column, the center of mass is at half the height, so the relevant displacement is 1082\frac{10-8}{2} or 862\frac{8-6}{2}, not 2m2 \, \text{m} directly.

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