Question:

Three solid spheres each of mass $m$ and diameter $d$ are stuck together such that the lines connecting the centres form an equilateral triangle of side of length $d$. The ratio $I_0/I_A$ of moment of inertia $I_0$ of the system about an axis passing the centroid and about center of any of the spheres $I_A$ and perpendicular to the plane of the triangle is :

Updated On: Sep 14, 2024
  • $\frac{15}{13}$
  • $\frac{13}{15}$
  • $\frac{13}{23}$
  • $\frac{23}{13}$
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The Correct Option is C

Solution and Explanation

From parallel axis theorem $I_{0}=3\times\left[\frac{2}{5}M\left(\frac{d}{2}\right)^{2}+M\left(\frac{d}{\sqrt{3}}\right)^{2}\right]=\frac{13}{10}Md^{2}$ $I_{A}=I_{0}+3M\left(\frac{d}{\sqrt{3}}\right)^{2}$ $=\frac{13}{10}Md^{2}+Md^{2}$ $=\frac{23}{10}Md^{2}$ $\frac{I_{0}}{I_{A}}=\frac{13}{23}$
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Concepts Used:

Moment of Inertia

Moment of inertia is defined as the quantity expressed by the body resisting angular acceleration which is the sum of the product of the mass of every particle with its square of a distance from the axis of rotation.

Moment of inertia mainly depends on the following three factors:

  1. The density of the material
  2. Shape and size of the body
  3. Axis of rotation

Formula:

In general form, the moment of inertia can be expressed as, 

I = m × r²

Where, 

I = Moment of inertia. 

m = sum of the product of the mass. 

r = distance from the axis of the rotation. 

M¹ L² T° is the dimensional formula of the moment of inertia. 

The equation for moment of inertia is given by,

I = I = ∑mi ri²

Methods to calculate Moment of Inertia:

To calculate the moment of inertia, we use two important theorems-

  • Perpendicular axis theorem
  • Parallel axis theorem