MCQMediumJEE 2025Torque & Angular Momentum

JEE Physics 2025 Question with Solution

An object of mass mm is projected from the origin in a vertical xyxy-plane at an angle 4545^\circ with the x-axis with an initial velocity v0v_0. The magnitude and direction of the angular momentum of the object with respect to the origin, when it reaches the maximum height, will be:

  • A

    mv0322g\frac{mv_0^3}{2\sqrt{2}g} along negative z-axis

  • B

    mv0322g\frac{mv_0^3}{2\sqrt{2}g} along positive z-axis

  • C

    mv0342g\frac{mv_0^3}{4\sqrt{2}g} along positive z-axis

  • D

    mv0342g\frac{mv_0^3}{4\sqrt{2}g} along negative z-axis

Answer

Correct answer:D

Step-by-step solution

Standard Method

Given: An object of mass mm is projected from the origin with initial speed v0v_0 at angle 4545^\circ in the vertical xyxy-plane.

Find: The magnitude and direction of angular momentum about the origin at maximum height.

At projection, the velocity components are

v0x=v0cos45=v02,v0y=v0sin45=v02v_{0x} = v_0 \cos 45^\circ = \frac{v_0}{\sqrt{2}}, \qquad v_{0y} = v_0 \sin 45^\circ = \frac{v_0}{\sqrt{2}}

At maximum height, the vertical component becomes zero, so

vy=0,vx=v02v_y = 0, \qquad v_x = \frac{v_0}{\sqrt{2}}

Time to reach maximum height is

t=v0yg=v02gt = \frac{v_{0y}}{g} = \frac{v_0}{\sqrt{2}g}

Hence the x-coordinate at maximum height is

x=v0xt=v02v02g=v022gx = v_{0x} t = \frac{v_0}{\sqrt{2}} \cdot \frac{v_0}{\sqrt{2}g} = \frac{v_0^2}{2g}

The y-coordinate at maximum height is

y=v0y22g=v024gy = \frac{v_{0y}^2}{2g} = \frac{v_0^2}{4g}

Angular momentum about the origin is

Lz=m(xvyyvx)L_z = m(xv_y - yv_x)

Substituting vy=0v_y = 0,

Lz=m(v024g)(v02)=mv0342gL_z = -m \left(\frac{v_0^2}{4g}\right) \left(\frac{v_0}{\sqrt{2}}\right) = -\frac{mv_0^3}{4\sqrt{2}g}

The negative sign indicates direction along the negative z-axis.

Therefore, the angular momentum is mv0342g\frac{mv_0^3}{4\sqrt{2}g} along the negative z-axis. The correct option is D.

Using Position Vector and Cross Product

Given: The projectile is launched at 4545^\circ with speed v0v_0 from the origin.

Find: Angular momentum at the highest point.

At the highest point, the momentum is purely horizontal because the vertical velocity becomes zero. So the momentum vector is along +x+x, while the position vector has both xx and yy components.

Write the position vector and momentum vector as

r=xi^+yj^,p=mvxi^\vec{r} = x\hat{i} + y\hat{j}, \qquad \vec{p} = m v_x \hat{i}

Then

L=r×p=(xi^+yj^)×(mvxi^)\vec{L} = \vec{r} \times \vec{p} = (x\hat{i} + y\hat{j}) \times (m v_x \hat{i})

Using cross product,

L=xi^×mvxi^+yj^×mvxi^\vec{L} = x\hat{i} \times m v_x \hat{i} + y\hat{j} \times m v_x \hat{i} L=0+ymvx(j^×i^)\vec{L} = 0 + y m v_x (\hat{j} \times \hat{i}) L=ymvxk^\vec{L} = -y m v_x \hat{k}

Now,

y=v024g,vx=v02y = \frac{v_0^2}{4g}, \qquad v_x = \frac{v_0}{\sqrt{2}}

So,

L=(v024g)m(v02)k^\vec{L} = - \left(\frac{v_0^2}{4g}\right) m \left(\frac{v_0}{\sqrt{2}}\right) \hat{k} L=mv0342gk^\vec{L} = -\frac{mv_0^3}{4\sqrt{2}g} \hat{k}

Thus the magnitude is mv0342g\frac{mv_0^3}{4\sqrt{2}g} and the direction is negative z-axis.

Common mistakes

  • Using the horizontal coordinate xx instead of the vertical coordinate yy in Lz=m(xvyyvx)L_z = m(xv_y - yv_x). This is wrong because at maximum height vy=0v_y = 0, so only the term involving yvxy v_x survives. Use Lz=myvxL_z = -m y v_x.

  • Assuming the angular momentum is zero at maximum height because the velocity is horizontal. This is wrong because angular momentum depends on both position and momentum, not on velocity direction alone. The particle is still at a non-zero distance from the origin.

  • Choosing the positive z-axis for direction. This is wrong because j^×i^=k^\hat{j} \times \hat{i} = -\hat{k}, so the cross product points along the negative z-axis. Check the vector order carefully in L=r×p\vec{L} = \vec{r} \times \vec{p}.

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