Rotational Motion Study Materials for Competitive Exams

Rotational Motion

Q. A cylinder rolls down an incline without slipping. If its mass is M and radius is R, what is the acceleration of its center of mass? (2020)

A. g/2
B. g/3
C. g/4
D. g/5

Solution

For rolling without slipping, a_cm = (2/3)g sin(θ).

Correct Answer: B — g/3

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Q. A disc of radius R and mass M is rotating about its axis with an angular velocity ω. What is its rotational kinetic energy? (2020)

A. (1/2)Iω²
B. (1/2)Mω²
C. Iω
D. Mω²

Solution

Rotational kinetic energy K.E. = (1/2)Iω². For a disc, I = (1/2)MR², thus K.E. = (1/4)MR²ω².

Correct Answer: A — (1/2)Iω²

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Q. A flywheel has a moment of inertia I and is rotating with an angular velocity ω. If a torque τ is applied, what is the angular acceleration? (2021)

A. τ/I
B. I/τ
C. ω/τ
D. Iω

Solution

From Newton's second law for rotation, τ = Iα, thus α = τ/I.

Correct Answer: A — τ/I

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Q. A mass m is attached to a string of length L and is swung in a vertical circle. What is the tension in the string at the top of the circle? (2023)

A. mg
B. 2mg
C. 3mg
D. 0

Solution

At the top, T + mg = mv²/L. T = mv²/L - mg.

Correct Answer: A — mg

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Q. A particle is moving in a circle of radius r with a constant speed v. What is the angular velocity? (2022)

A. v/r
B. r/v
C. vr
D. v²/r

Solution

Angular velocity ω = v/r.

Correct Answer: A — v/r

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Q. A particle moves in a circular path of radius r with a constant speed v. What is the centripetal acceleration? (2022)

A. v²/r
B. vr
C. r/v
D. v/r

Solution

Centripetal acceleration a_c = v²/r.

Correct Answer: A — v²/r

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Q. A rotating object has a moment of inertia I and an angular velocity ω. What is its rotational kinetic energy? (2020)

A. (1/2)Iω
B. (1/2)Iω²
C. Iω²
D. I/2ω²

Solution

Rotational kinetic energy K.E. = (1/2)Iω².

Correct Answer: B — (1/2)Iω²

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Q. A rotating object has an angular momentum L. If its moment of inertia is halved and angular velocity is doubled, what is the new angular momentum? (2022)

A. L
B. 2L
C. 3L
D. 4L

Solution

L = Iω, if I is halved and ω is doubled, L' = (1/2)(2ω) = L.

Correct Answer: B — 2L

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Q. A solid cylinder rolls down an incline. If its height is h, what is its linear speed at the bottom? (2023)

A. √(gh)
B. √(2gh)
C. √(3gh)
D. √(4gh)

Solution

Using conservation of energy, potential energy converts to kinetic energy. For a solid cylinder, v = √(2gh).

Correct Answer: B — √(2gh)

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Q. A solid sphere of radius R rolls without slipping down an incline of height h. What is its speed at the bottom of the incline? (2021)

A. √(2gh)
B. √(3gh)
C. √(4gh)
D. √(5gh)

Solution

Using conservation of energy, potential energy at the top = kinetic energy at the bottom. For a solid sphere, v = √(5gh/7). Thus, speed at the bottom is √(3gh).

Correct Answer: B — √(3gh)

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Q. A solid sphere of radius R rolls without slipping down an inclined plane of height h. What is the speed of the center of mass at the bottom of the incline? (2021)

A. √(2gh)
B. √(3gh)
C. √(4gh)
D. √(5gh)

Solution

Using conservation of energy, potential energy at height h = kinetic energy at the bottom. For a solid sphere, v = √(3gh).

Correct Answer: B — √(3gh)

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Q. A uniform rod of length L is pivoted at one end and released from rest. What is the angular speed just before it hits the ground? (2019)

A. √(3g/L)
B. √(2g/L)
C. √(g/L)
D. √(4g/L)

Solution

Using conservation of energy, potential energy converts to rotational kinetic energy. Angular speed ω = √(3g/L).

Correct Answer: B — √(2g/L)

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Q. A uniform rod of length L is pivoted at one end and released from rest. What is the angular speed when it reaches the vertical position? (2019)

A. √(3g/L)
B. √(2g/L)
C. √(g/L)
D. √(4g/L)

Solution

Using conservation of energy, potential energy converts to rotational kinetic energy. Angular speed ω = √(3g/L).

Correct Answer: B — √(2g/L)

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Q. A wheel of radius 0.5 m is rotating with an angular speed of 10 rad/s. What is the linear speed of a point on the edge of the wheel? (2022)

A. 5 m/s
B. 10 m/s
C. 15 m/s
D. 20 m/s

Solution

Linear speed v = rω = 0.5 m * 10 rad/s = 5 m/s.

Correct Answer: B — 10 m/s

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Q. A wheel rotates with a constant angular acceleration α. If its initial angular velocity is ω₀, what is its angular velocity after time t? (2023)

A. ω₀ + αt
B. ω₀ - αt
C. αt²
D. ω₀t

Solution

Using the equation of motion for rotation, ω = ω₀ + αt.

Correct Answer: A — ω₀ + αt

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Rotational Motion MCQ & Objective Questions

Understanding "Rotational Motion" is crucial for students preparing for various school and competitive exams. This topic not only forms a significant part of the physics syllabus but also enhances your analytical skills. Practicing MCQs and objective questions on rotational motion can significantly improve your exam performance by helping you grasp essential concepts and apply them effectively.

What You Will Practise Here

Key concepts of rotational motion including angular displacement, velocity, and acceleration.
Formulas related to torque, moment of inertia, and angular momentum.
Definitions of important terms such as centripetal force and rotational equilibrium.
Diagrams illustrating rotational dynamics and the relationship between linear and angular motion.
Applications of rotational motion in real-life scenarios and engineering.
Important theorems related to rotational motion, such as the parallel axis theorem.
Practice questions that challenge your understanding and application of these concepts.

Exam Relevance

"Rotational Motion" is a key topic in the physics curriculum for CBSE, State Boards, NEET, and JEE. Students can expect questions that test their understanding of basic principles, calculations involving formulas, and application-based scenarios. Common question patterns include numerical problems, conceptual questions, and diagram-based queries that require a solid grasp of the subject.

Common Mistakes Students Make

Confusing linear motion concepts with rotational motion principles.
Misapplying formulas, especially when transitioning between linear and angular quantities.
Overlooking the significance of direction in vector quantities like torque and angular momentum.
Failing to interpret diagrams correctly, which can lead to incorrect answers in application-based questions.
Neglecting to practice enough numerical problems, which are essential for mastering this topic.

FAQs

Question: What are the key formulas I should remember for rotational motion?
Answer: Important formulas include torque (τ = r × F), moment of inertia (I = Σmr²), and angular momentum (L = Iω).

Question: How can I improve my understanding of rotational motion?
Answer: Regular practice of MCQs and objective questions, along with conceptual clarity, will greatly enhance your understanding.

Now is the time to take your preparation to the next level! Dive into our practice MCQs on rotational motion and solidify your understanding of this essential topic. Test yourself and boost your confidence for the upcoming exams!

Rotational Motion

Rotational Motion MCQ & Objective Questions

What You Will Practise Here

Exam Relevance

Common Mistakes Students Make

FAQs

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