MCQMediumJEE 2026Torque & Angular Momentum

JEE Physics 2026 Question with Solution

A uniform rod of mass mm and length ll suspended by means of two identical inextensible light strings as shown in figure. Tension in one string immediately after the other string is cut, is _____ (gg = acceleration due to gravity).

A horizontal uniform rod AB is suspended by two identical vertical light strings from a fixed support above, one at each end of the rod, with the rod length marked as l.
  • A

    mg3\frac{mg}{3}

  • B

    mg2\frac{mg}{2}

  • C

    mg4\frac{mg}{4}

  • D

    mgmg

Answer

Correct answer:C

Step-by-step solution

Standard Method

Given: A uniform rod of mass mm and length ll is supported by two identical vertical strings. One string is cut, and we need the tension TT in the remaining string immediately after the cut.

Find: The value of TT just after one string is cut.

Immediately after the cut, the rod starts rotating about the end where the remaining string is attached. Use rotational motion about that end and then relate it to the acceleration of the center of mass.

The torque about the pivot is due only to weight:

τ=mgl2\tau = mg \cdot \frac{l}{2}

The moment of inertia of a uniform rod about one end is:

I=13ml2I = \frac{1}{3}ml^2

Using:

τ=Iα\tau = I\alpha

we get

mgl2=(13ml2)αmg\frac{l}{2} = \left(\frac{1}{3}ml^2\right)\alpha

So,

α=3g2l\alpha = \frac{3g}{2l}

Force and Rotation Relation

Now relate angular acceleration to the linear acceleration of the center of mass. Since the center of mass is at distance l2\frac{l}{2} from the pivot,

acm=l2αa_{cm} = \frac{l}{2}\alpha

Substituting α=3g2l\alpha = \frac{3g}{2l},

acm=l2(3g2l)=3g4a_{cm} = \frac{l}{2}\left(\frac{3g}{2l}\right) = \frac{3g}{4}

Net Force on Center of Mass

For vertical motion of the center of mass,

mgT=macmmg - T = ma_{cm}

Substitute acm=3g4a_{cm} = \frac{3g}{4}:

mgT=m(3g4)mg - T = m\left(\frac{3g}{4}\right)

Hence,

T=mg3mg4=mg4T = mg - \frac{3mg}{4} = \frac{mg}{4}

Therefore, the tension in the remaining string immediately after the other is cut is mg4\frac{mg}{4}. The correct option is C.

Common mistakes

  • Assuming the center of mass falls with acceleration gg is incorrect. The rod is a rigid body constrained to rotate about the remaining end, so the center of mass has acceleration less than gg. First find α\alpha, then use acm=l2αa_{cm} = \frac{l}{2}\alpha.

  • Including the tension as a torque about the pivot is wrong. The remaining string acts at the pivot point, so its moment arm is zero. Only weight mgmg produces torque about that point.

  • Using the moment of inertia of the rod about its center, 112ml2\frac{1}{12}ml^2, is incorrect here. Since the rod rotates about one end immediately after the cut, the correct moment of inertia is 13ml2\frac{1}{3}ml^2.

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