NVAMediumJEE 2023Kinetic Energy & Work-Energy Theorem

JEE Physics 2023 Question with Solution

A particle of mass 10g10 \, \text{g} moves in a straight line with retardation 2x2x, where xx is the displacement in SI units. Its loss of kinetic energy for the above displacement is (10/x)nJ(10/x)^{-n} \, \text{J}. The value of nn will be:

Answer

Correct answer:2

Step-by-step solution

Standard Method

Given: Mass of the particle is m=10g=102kgm = 10 \, \text{g} = 10^{-2} \, \text{kg} and retardation is a=2xa = -2x.

Find: The value of nn if the loss of kinetic energy is (10/x)nJ(10/x)^{-n} \, \text{J}.

Using

a=vdvdxa = v\frac{dv}{dx}

we get

vdvdx=2xv\frac{dv}{dx} = -2x

So,

vdv=2xdxv \, dv = -2x \, dx

Integrating from initial velocity v1v_1 to final velocity v2v_2, and displacement from 00 to xx,

v1v2vdv=20xxdx\int_{v_1}^{v_2} v \, dv = -2 \int_0^x x \, dx v222v122=2x22\frac{v_2^2}{2} - \frac{v_1^2}{2} = -\frac{2x^2}{2} v222v122=x2\frac{v_2^2}{2} - \frac{v_1^2}{2} = -x^2

Multiplying by mm,

mv122mv222=mx2\frac{mv_1^2}{2} - \frac{mv_2^2}{2} = mx^2

Hence, loss of kinetic energy is

ΔKEloss=mx2=102x2\Delta KE_{\text{loss}} = mx^2 = 10^{-2}x^2

Now,

102x2=(10x)210^{-2}x^2 = \left(\frac{10}{x}\right)^{-2}

Comparing with the given form (10/x)n(10/x)^{-n}, we get

n=2n = 2

Therefore, the value of nn is 22.

Work-Energy Theorem Route

Given: The retardation varies with displacement as a=2xa = -2x.

Find: The exponent nn in the loss of kinetic energy expression.

By the work-energy idea, the retardation causes a decrease in kinetic energy. First rewrite acceleration as

a=vdvdxa = v\frac{dv}{dx}

Thus,

vdvdx=2xv\frac{dv}{dx} = -2x vdv=2xdxv \, dv = -2x \, dx

Integrating,

v1v2vdv=20xxdx\int_{v_1}^{v_2} v \, dv = -2\int_0^x x \, dx v22v122=x2\frac{v_2^2 - v_1^2}{2} = -x^2

So,

12m(v22v12)=mx2\frac{1}{2}m(v_2^2 - v_1^2) = -mx^2

This means the change in kinetic energy is

KE2KE1=mx2KE_2 - KE_1 = -mx^2

Therefore, the loss of kinetic energy is

KE1KE2=mx2KE_1 - KE_2 = mx^2

Now substitute m=10g=0.01kg=102kgm = 10 \, \text{g} = 0.01 \, \text{kg} = 10^{-2} \, \text{kg}:

KE1KE2=102x2JKE_1 - KE_2 = 10^{-2}x^2 \, \text{J}

Also,

(10x)2=(x10)2=x2100=102x2\left(\frac{10}{x}\right)^{-2} = \left(\frac{x}{10}\right)^2 = \frac{x^2}{100} = 10^{-2}x^2

Hence the given expression matches when

n=2n = 2

Therefore, the required value is 22.

Common mistakes

  • Using a=dvdta = \frac{dv}{dt} directly with displacement xx is incorrect here because acceleration is given as a function of displacement, not time. Use a=vdvdxa = v\frac{dv}{dx} instead.

  • Treating 10g10 \, \text{g} as 10kg10 \, \text{kg} gives a wrong kinetic energy loss by a factor of 10001000. Convert mass first: 10g=102kg10 \, \text{g} = 10^{-2} \, \text{kg}.

  • Confusing change in kinetic energy with loss of kinetic energy leads to a sign error. Here KE2KE1=mx2KE_2 - KE_1 = -mx^2, so the loss is KE1KE2=mx2KE_1 - KE_2 = mx^2.

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