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Question: A circular disc of radius R and thickness \(\dfrac{R}{6}\) has moment of inertia I about an axis pas...

A circular disc of radius R and thickness R6\dfrac{R}{6} has moment of inertia I about an axis passing through its Centre perpendicular to its plane. It is melted and recast into a solid sphere. The moment of inertia of the sphere about its diameter is
A. II
B. 2I8\dfrac{{2I}}{8}
C. I5\dfrac{I}{5}
D. I10\dfrac{I}{{10}}

Explanation

Solution

Moment of inertia is a resisting property of a rigid body, when the body tends to rotate. It is defined as a summation of mass of particles multiplied by square of its distance from the axis.

Complete step by step solution:
As we know that if an object of any shape is melted and recast into another shape, then its volume remains the same(or say conserved),.
For Circular Disc,
Radius of circular disc  =  RRadius{\text{ }}of{\text{ }}circular{\text{ }}disc\; = \;R ,
Thickness  of  circular disc =R6Thickness\;of\;circular{\text{ }}disc{\text{ }} = \dfrac{R}{6} ,
VolumeVolume of circular disc =πR2×R6of{\text{ }}circular{\text{ }}disc{\text{ }} = \pi {R^2} \times \dfrac{R}{6} .
For Solid Sphere,
Let radius of solid sphere be r,
Volume of solid sphere =  4πr33Volume{\text{ }}of{\text{ }}solid{\text{ }}sphere{\text{ }} = \;\dfrac{{4\pi {r^3}}}{3} ,
Mass of circular disc = Mass of solid sphereMass{\text{ }}of{\text{ }}circular{\text{ }}disc{\text{ }} = {\text{ }}Mass{\text{ }}of{\text{ }}solid{\text{ }}sphere

As volume remains conserved,
Volume of circular disc = Volume of solid sphereVolume{\text{ }}of{\text{ }}circular{\text{ }}disc{\text{ }} = {\text{ }}Volume{\text{ }}of{\text{ }}solid{\text{ }}sphere
πR2×R6=4πr33\pi {R^2} \times \dfrac{R}{6} = \dfrac{{4\pi {r^3}}}{3}
After solving it, you will get
r=R2(equation1)r = \dfrac{R}{2}\left( {equation \to 1} \right)
Till now, we have find the radius of solid sphere,
Let’s move to our last step, that is to find a moment of inertia of the solid sphere.
Moment of inertia of circular disc=I(given)Moment{\text{ }}of{\text{ }}inertia{\text{ }}of{\text{ }}circular{\text{ }}disc = I\left( {given} \right)
MR22=I\dfrac{{M{R^2}}}{2} = I
M=2×IR2(equation2)M = \dfrac{{2 \times I}}{{{R^2}}}\left( {equation \to 2} \right)
Moment of inertia of solid sphere about its diameter =2Mr25\dfrac{{2M{r^2}}}{5}
Now, put the values of M and r from equation 1 and equation 2.
=2×2×I5×R2×R24= \dfrac{{2 \times 2 \times I}}{{5 \times {R^2}}} \times \dfrac{{{R^2}}}{4}
=I5= \dfrac{I}{5}

\therefore Option(C) is correct.

Note: Moment of inertia of different rigid bodies is different.
Volume before melting of an object remains equal to Volume after melting.