From a Circular Disc of Radius r and Mass 9m Solution 2026 - 9mgamestore

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From a Circular Disc of Radius r and Mass 9m Solution 2026

From a Circular Disc of Radius r and Mass 9m – Complete Solution Guide

From a Circular Disc of Radius r and Mass 9m
From a Circular Disc of Radius r and Mass 9m 


The phrase "from a circular disc of radius r and mass 9m" commonly appears in Physics and Engineering Mechanics problems involving the moment of inertia, center of mass, rotational dynamics, and removal of a smaller disc from a larger circular disc.

Many students encounter such questions in competitive examinations, including JEE Main, JEE Advanced, NEET, and various university entrance tests. These problems test conceptual understanding of rotational motion and mass distribution.

In this guide, we will understand how to approach questions based on a circular disc of radius r and mass 9m, the formulas involved, common shortcuts, and examination strategies.

Understanding the Circular Disc

A circular disc is a two-dimensional object having uniform thickness and mass distribution.

Given:

Since the mass is uniformly distributed, the surface mass density is constant throughout the disc.

Surface density:

σ = Total Mass / Area

Area of disc:

A = πr²

Therefore,

σ = 9m / πr²

This density concept becomes extremely useful when a smaller section is removed from the disc.

Moment of Inertia of a Circular Disc

One of the most frequently asked questions involving a circular disc of radius r and mass 9m relates to the moment of inertia.

Moment of inertia about the central axis:

I = ½MR²

Substituting:

M = 9m

R = r

Therefore,

I = ½ × 9m × r²

I = 9mr²/2

This is the moment of inertia about an axis passing through the center and perpendicular to the plane of the disc.

When a Smaller Disc is Removed

A common examination problem states:

"A smaller disc of radius r/3 is removed from a larger disc of radius r and mass 9m."

Step 1: Find Density

σ = 9m / πr²

Step 2: Area of Smaller Disc

Area = π(r/3)²

Area = πr²/9

Step 3: Mass of Smaller Disc

Mass = Density × Area

Mass = (9m/πr²) × (πr²/9)

Mass = m

Thus, a smaller disc of radius r/3 removed from the larger disc has mass m.

This result appears very frequently in objective examinations.

Center of Mass Concept

When material is removed from a symmetric body, the center of mass shifts.

To solve such problems:

  1. Consider the removed portion as negative mass.

  2. Use center of mass equations.

  3. Calculate displacement from the original center.

Formula:

x = (Σmx)/(Σm)

The removed disc contributes negative mass.

This shortcut greatly simplifies calculations.

Parallel Axis Theorem

Another important concept used in circular disc problems is the parallel axis theorem.

Formula:

I = Icm + Md²

Where:

  • I = Moment of inertia about required axis

  • Icm = Moment of inertia about center of mass

  • M = Mass

  • d = Distance between axes

Students should remember this theorem because many questions involving removed discs require it.

Rotational Dynamics Applications

Circular disc problems frequently appear in rotational dynamics.

Important equations:

Torque:

τ = Iα

Angular momentum:

L = Iω

Rotational kinetic energy:

K = ½Iω²

When the moment of inertia changes due to removal of a smaller portion, all these quantities are affected.

Competitive Exam Perspective

Questions based on a circular disc of radius r and mass 9m are popular because they combine:

  • Geometry

  • Mass density

  • Rotational mechanics

  • Center of mass

  • Moment of inertia

Examiners often create variations involving:

  • Semicircular cuts

  • Circular holes

  • Eccentric removals

  • Composite bodies

Students who understand density-based calculations can solve such problems quickly.

Shortcut Method

Whenever a disc has uniform density:

Mass ∝ Area

Therefore:

Mass Ratio = Area Ratio

For example:

Large disc radius = r

Small disc radius = r/3

Area ratio:

π(r/3)² : πr²

= 1 : 9

Therefore:

Mass ratio = 1 : 9

If large mass = 9m

Small mass = m

This shortcut saves significant time in exams.

Common Mistakes

Ignoring Uniform Density

Students often use incorrect mass values without calculating density.

Wrong Radius Substitution

Always square the radius carefully.

Forgetting Negative Mass

For removed sections, use negative mass while calculating center of mass.

Incorrect Axis Selection

Read the question carefully before applying the moment of inertia formula.

Sample Numerical Example

Question:

A circular disc of radius r and mass 9m has a smaller disc of radius r/3 removed from it. Find the mass of the removed disc.

Solution:

Density:

σ = 9m/πr²

Area of smaller disc:

π(r/3)²

= πr²/9

Mass removed:

σ × area

= (9m/πr²) × (πr²/9)

= m

Answer:

Mass removed = m

Exam Preparation Tips

  1. Memorize standard moment of inertia formulas.

  2. Practice center of mass problems daily.

  3. Learn area-to-mass conversion shortcuts.

  4. Revise parallel axis theorem regularly.

  5. Solve previous year JEE and NEET questions.

Frequently Asked Questions

What is the moment of inertia of a disc of radius r and mass 9m?

I = 9mr²/2

Why is density important?

Density helps determine the mass of removed portions.

How do we calculate the mass of a smaller removed disc?

Mass is proportional to area because density is uniform.

Which exams ask such questions?

JEE Main, JEE Advanced, NEET, BITSAT, and university engineering entrance examinations.


Problems involving a circular disc of radius r and mass 9m are among the most important topics in rotational mechanics. By understanding density, moment of inertia, center of mass, and rotational dynamics, students can solve even advanced variations quickly and accurately. Consistent practice and proper application of formulas are the keys to mastering these questions in competitive examinations.


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