MCQMediumJEE 2025Circular Motion Dynamics

JEE Physics 2025 Question with Solution

A car of mass mm moves on a banked road having radius rr and banking angle θ\theta. To avoid slipping from the banked road, the maximum permissible speed of the car is v0v_0. The coefficient of friction μ\mu between the wheels of the car and the banked road is:

  • A

    μ=v02+rgtanθrgv02tanθ\mu = \frac{v_0^2 + rg \tan \theta}{rg - v_0^2 \tan \theta}

  • B

    μ=v02+rgtanθrg+v02tanθ\mu = \frac{v_0^2 + rg \tan \theta}{rg + v_0^2 \tan \theta}

  • C

    μ=v02rgtanθrg+v02tanθ\mu = \frac{v_0^2 - rg \tan \theta}{rg + v_0^2 \tan \theta}

  • D

    μ=v02rgtanθrgv02tanθ\mu = \frac{v_0^2 - rg \tan \theta}{rg - v_0^2 \tan \theta}

Answer

Correct answer:C

Step-by-step solution

Force balance on the banked road

Given: A car of mass mm moves on a banked road of radius rr with banking angle θ\theta. The maximum permissible speed is v0v_0.

Find: The coefficient of friction μ\mu.

At the maximum permissible speed, the car is at the verge of slipping, so friction is at its limiting value. The required centripetal force is

Fc=mv02rF_c = \frac{mv_0^2}{r}

The forces acting are weight mgmg downward, normal reaction NN perpendicular to the road, and friction acting along the slope.

Using the force balance written in the solution:

Ncosθ+μNsinθ=mgN \cos \theta + \mu N \sin \theta = mg NsinθμNcosθ=mv02rN \sin \theta - \mu N \cos \theta = \frac{mv_0^2}{r}

From the first equation,

N=mgcosθ+μsinθN = \frac{mg}{\cos \theta + \mu \sin \theta}

Substitute this into the horizontal equation:

mgcosθ+μsinθsinθμmgcosθ+μsinθcosθ=mv02r\frac{mg}{\cos \theta + \mu \sin \theta} \sin \theta - \mu \frac{mg}{\cos \theta + \mu \sin \theta} \cos \theta = \frac{mv_0^2}{r}

On simplifying, we obtain

μ=v02rgtanθrg+v02tanθ\mu = \frac{v_0^2 - rg \tan \theta}{rg + v_0^2 \tan \theta}

Therefore, the correct option is C.

Using the resolved-force equations from the first approach

Given: A car moves on a banked road with radius rr, banking angle θ\theta, and maximum permissible speed v0v_0.

Find: The coefficient of friction μ\mu.

The first approach resolves forces parallel and perpendicular to the incline.

Perpendicular balance:

Ncosθ=mg+mv02rsinθN \cos \theta = mg + \frac{mv_0^2}{r} \sin \theta

So,

N=mg+mv02rsinθcosθN = \frac{mg + \frac{mv_0^2}{r} \sin \theta}{\cos \theta}

Parallel balance:

Nsinθmv02rcosθ=μNcosθN \sin \theta - \frac{mv_0^2}{r} \cos \theta = \mu N \cos \theta

Substituting the value of NN:

(mg+mv02rsinθcosθ)sinθmv02rcosθ=μ(mg+mv02rsinθcosθ)cosθ\left( \frac{mg + \frac{mv_0^2}{r} \sin \theta}{\cos \theta} \right) \sin \theta - \frac{mv_0^2}{r} \cos \theta = \mu \left( \frac{mg + \frac{mv_0^2}{r} \sin \theta}{\cos \theta} \right) \cos \theta

Simplifying gives

μ=v02rgtanθrg+v02tanθ\mu = \frac{v_0^2 - rg \tan \theta}{rg + v_0^2 \tan \theta}

Hence, the coefficient of friction is v02rgtanθrg+v02tanθ\frac{v_0^2 - rg \tan \theta}{rg + v_0^2 \tan \theta}, so the correct option is C.

Common mistakes

  • Taking friction in the wrong direction. At maximum permissible speed, the car tends to slip up the bank, so friction must oppose that tendency. First identify the impending motion, then choose the direction of friction accordingly.

  • Using the frictionless banked-road condition tanθ=v2rg\tan \theta = \frac{v^2}{rg} directly. That relation is valid only when μ=0\mu = 0. Here friction is present, so both normal reaction and friction must be included in the force balance.

  • Confusing vertical-horizontal resolution with resolution along and perpendicular to the incline. Either method works, but the equations must be written consistently in one coordinate system. Mixing components from different resolutions leads to incorrect signs.

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