MCQMediumJEE 2026Velocity & Acceleration

JEE Physics 2026 Question with Solution

A particle of mass mm falls from rest through a resistive medium having resistive force F=kvF=-kv, where vv is the velocity of the particle and kk is a constant. Which of the following graphs represents velocity vv versus time tt?

Four velocity versus time graphs labeled 1 to 4, with graph 1 rising from the origin and flattening, graph 2 rising steeply, graph 3 straight line increasing, and graph 4 decreasing with time.
  • A

    Graph 1

  • B

    Graph 2

  • C

    Graph 3

  • D

    Graph 4

Answer

Correct answer:A

Step-by-step solution

Standard Method

Given: A particle of mass mm falls from rest in a resistive medium with resistive force F=kvF=-kv.

Find: Which graph correctly represents vv versus tt.

For downward motion, take downward direction as positive. Then the forces are weight mgmg downward and resistive force kvkv upward.

So, the equation of motion is

mdvdt=mgkvm\frac{dv}{dt}=mg-kv

Rearranging,

dvdt+kmv=g\frac{dv}{dt}+\frac{k}{m}v=g

This is a first-order linear differential equation.

Using the integrating factor,

I.F.=ekmt\text{I.F.}=e^{\frac{k}{m}t}

we get the solution

v(t)=mgk(1ekmt)v(t)=\frac{mg}{k}\left(1-e^{-\frac{k}{m}t}\right)

Now analyze the result:

  • At t=0t=0, v(0)=0v(0)=0, so the particle starts from rest.
  • As tt\to\infty, vmgkv\to\frac{mg}{k}, which is the terminal velocity.

Therefore, velocity increases from zero, rises rapidly at first, and then gradually levels off toward a horizontal asymptote.

So the correct graph is the one that starts at the origin and approaches a constant value asymptotically. Graph 1 matches this behavior.

Therefore, the correct option is A.

Behavior of the velocity-time curve

Given: Resistive force is proportional to velocity.

Find: The qualitative shape of the vv-tt graph.

Whenever the resistive force is proportional to speed, the net downward force decreases as vv increases. Hence the acceleration is not constant.

Initially, when v=0v=0,

dvdt=g\frac{dv}{dt}=g

so the particle begins with maximum acceleration.

As time increases, kvkv increases, so

dvdt=gkmv\frac{dv}{dt}=g-\frac{k}{m}v

becomes smaller and smaller.

Thus the slope of the vv-tt graph decreases continuously, and eventually becomes nearly zero when terminal velocity is approached.

This rules out:

  • Graph 2, because it shows the slope increasing.
  • Graph 3, because it shows constant slope, which would mean constant acceleration.
  • Graph 4, because it shows decreasing velocity.

Hence the only correct graph is Graph 1, so the correct option is A.

Common mistakes

  • Assuming the acceleration remains constant at gg throughout the motion. This is wrong because the resistive force kvkv increases with speed and reduces the net force. Instead, use mdvdt=mgkvm\frac{dv}{dt}=mg-kv and note that the slope of the graph must decrease with time.

  • Choosing the straight-line graph by comparing with free fall in vacuum. This is wrong because linear increase of vv with tt occurs only when there is no resistive force. Here the speed approaches terminal velocity asymptotically.

  • Ignoring the initial condition that the particle falls from rest. This is wrong because the correct graph must start from v=0v=0 at t=0t=0. Any graph not starting at the origin is inconsistent with the given condition.

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