MCQEasyJEE 2025Force on Moving Charge

JEE Physics 2025 Question with Solution

An electron with mass mm with an initial velocity (t=0)v=v0(v0>0)(t = 0) \, \vec{v} = \vec{v_0} \, (v_0 > 0) enters a magnetic field B=Bj^\vec{B} = B \hat{j}. If the initial de-Broglie wavelength at t=0t = 0 is λ0\lambda_0, then its value after time tt would be:

  • A

    λ01+e2B2t2m2\frac{\lambda_0}{\sqrt{1 + \frac{e^2 B^2 t^2}{m^2}}}

  • B

    λ01+e2B2t2m2\lambda_0 \sqrt{1 + \frac{e^2 B^2 t^2}{m^2}}

  • C

    λ0\lambda_0

  • D

    λ0\lambda_0

Answer

Correct answer:D

Step-by-step solution

Standard Method

Given: An electron of mass mm and charge e-e enters a uniform magnetic field B=Bj^\vec{B}=B\hat{j} with initial velocity v=v0\vec{v}=\vec{v_0}. The initial de-Broglie wavelength is λ0\lambda_0.

Find: The de-Broglie wavelength after time tt.

Concept used: The magnetic force is always perpendicular to the instantaneous velocity, so it changes only the direction of motion, not the speed.

Using Lorentz force,

F=e(v×B)\vec{F}=-e(\vec{v}\times\vec{B})

Since this force is perpendicular to v\vec{v}, the magnitude of velocity remains constant.

The de-Broglie wavelength is

λ=hp=hmv\lambda=\frac{h}{p}=\frac{h}{mv}

Because the speed vv remains unchanged, the momentum magnitude p=mvp=mv also remains unchanged.

Therefore,

λ(t)=hmv0=λ0\lambda(t)=\frac{h}{mv_0}=\lambda_0

So the de-Broglie wavelength remains constant with time.

The solution states that the correct option is D. However, in the listed options, the visible value λ0\lambda_0 appears more than once, so the answer is taken from the solution authority.

Therefore, the correct option is D, and the wavelength after time tt is λ0\lambda_0.

Speed-Constancy Trick

Given: The electron moves only under a magnetic field.

Find: Whether its de-Broglie wavelength changes with time.

A magnetic field does no work on a charged particle, so it cannot change the particle's kinetic energy or speed. Since

λ=hmv\lambda=\frac{h}{mv}

and mm is constant, an unchanged speed means an unchanged de-Broglie wavelength.

Hence,

λ(t)=λ0\lambda(t)=\lambda_0

Therefore, the correct option is D.

Common mistakes

  • Assuming the magnetic field changes the speed of the electron. This is wrong because magnetic force is always perpendicular to velocity and does no work. Only the direction changes; use constant speed while evaluating de-Broglie wavelength.

  • Using the vector change in velocity to conclude that momentum magnitude changes. This is wrong because only the direction of p\vec{p} changes in circular motion, not its magnitude. Use p=mvp = mv with constant vv.

  • Substituting time tt into the expression for wavelength as if there were linear acceleration. This is wrong because there is no tangential acceleration here. First identify that the motion is under a purely magnetic force, then keep λ\lambda constant.

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