Rolling Motion Study Materials for Competitive Exams

Rolling Motion

Q. A solid cylinder and a hollow cylinder of the same mass and radius are released from rest at the same height. Which one will have a greater speed at the bottom?

A. Solid cylinder
B. Hollow cylinder
C. Both have the same speed
D. Depends on the mass

Solution

The solid cylinder has a smaller moment of inertia compared to the hollow cylinder, thus it will have a greater speed at the bottom.

Correct Answer: A — Solid cylinder

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Q. A solid cylinder and a hollow cylinder of the same mass and radius roll down the same incline. Which one reaches the bottom first?

A. Solid cylinder
B. Hollow cylinder
C. Both reach at the same time
D. Depends on the angle of incline

Solution

The solid cylinder reaches the bottom first because it has a smaller moment of inertia compared to the hollow cylinder.

Correct Answer: A — Solid cylinder

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Q. A solid cylinder of radius R rolls down a frictionless incline. What is the ratio of its translational kinetic energy to its total kinetic energy at the bottom?

A. 1:1
B. 2:1
C. 1:2
D. 3:1

Solution

At the bottom, total kinetic energy = translational + rotational. For a solid cylinder, the ratio of translational to total kinetic energy is 2:1.

Correct Answer: B — 2:1

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Q. A solid cylinder rolls down an incline of angle θ. What is the ratio of translational kinetic energy to total kinetic energy at the bottom?

A. 1/3
B. 2/5
C. 1/2
D. 3/5

Solution

For a solid cylinder, the ratio of translational kinetic energy to total kinetic energy is 2/5.

Correct Answer: B — 2/5

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Q. A solid sphere and a hollow sphere of the same mass and radius are released from rest at the same height. Which one reaches the bottom first?

A. Solid sphere
B. Hollow sphere
C. Both reach at the same time
D. Depends on the surface

Solution

The solid sphere reaches the bottom first because it has a lower moment of inertia, allowing it to convert more potential energy into translational kinetic energy.

Correct Answer: A — Solid sphere

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Q. A solid sphere of radius R rolls without slipping down an inclined plane of angle θ. What is the acceleration of the center of mass of the sphere?

A. g sin(θ)
B. g sin(θ)/2
C. g sin(θ)/3
D. g sin(θ)/4

Solution

The acceleration of the center of mass of a solid sphere rolling down an incline is given by a = g sin(θ) / (1 + (2/5)) = g sin(θ) / (7/5) = (5/7) g sin(θ).

Correct Answer: A — g sin(θ)

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Q. A solid sphere rolls down a frictionless incline. If it starts from rest, what is its final velocity at the bottom of the incline of height h?

A. √(gh)
B. √(5gh/7)
C. √(2gh)
D. √(3gh)

Solution

Using conservation of energy, the final velocity of the solid sphere at the bottom is v = √(5gh/7).

Correct Answer: D — √(3gh)

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Q. A solid sphere rolls down a hill without slipping. If the height of the hill is h, what is the speed of the sphere at the bottom of the hill?

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

Solution

Using conservation of energy, potential energy at the top (mgh) converts to kinetic energy (1/2 mv^2 + 1/2 Iω^2). For a solid sphere, I = (2/5)mr^2 and ω = v/r. Solving gives v = √(2gh).

Correct Answer: A — √(2gh)

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Q. A solid sphere rolls down an inclined plane without slipping. What is the ratio of its translational kinetic energy to its total kinetic energy at the bottom?

A. 1:2
B. 2:3
C. 1:3
D. 1:1

Solution

The total kinetic energy is the sum of translational and rotational kinetic energy. For a solid sphere, the ratio of translational to total kinetic energy is 2:3.

Correct Answer: B — 2:3

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Q. A solid sphere rolls down an inclined plane without slipping. What is the ratio of its translational kinetic energy to its total kinetic energy at the bottom of the incline?

A. 1:2
B. 2:3
C. 1:3
D. 1:1

Solution

The total kinetic energy is the sum of translational and rotational kinetic energy. For a solid sphere, the ratio of translational to total kinetic energy is 2:5, which simplifies to 2:3.

Correct Answer: B — 2:3

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Q. A sphere rolls down a ramp of height h. What is the total mechanical energy at the top?

A. mgh
B. 1/2 mv^2
C. mgh + 1/2 mv^2
D. 0

Solution

The total mechanical energy at the top is purely potential energy, which is mgh.

Correct Answer: A — mgh

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Q. A sphere rolls down a ramp. If the height of the ramp is h, what is the speed of the sphere at the bottom assuming no energy loss?

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

Solution

Using conservation of energy, the potential energy at height h converts to kinetic energy at the bottom, giving speed √(2gh).

Correct Answer: A — √(2gh)

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Q. A sphere rolls on a flat surface with a speed v. What is the kinetic energy of the sphere?

A. (1/2)mv^2
B. (1/2)mv^2 + (1/5)mv^2
C. (1/2)mv^2 + (2/5)mv^2
D. (1/2)mv^2 + (3/5)mv^2

Solution

The total kinetic energy of a rolling sphere is the sum of translational and rotational kinetic energy, which is (1/2)mv^2 + (2/5)mv^2.

Correct Answer: C — (1/2)mv^2 + (2/5)mv^2

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Q. A sphere rolls without slipping on a flat surface. If it has a radius R and rolls with a speed v, what is its angular speed?

A. v/R
B. 2v/R
C. v/2R
D. v²/R

Solution

The angular speed ω of a rolling sphere is given by ω = v/R.

Correct Answer: A — v/R

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Q. A wheel of radius R rolls on a flat surface. If it rolls without slipping, what is the distance traveled by the center of mass after one complete rotation?

A. 2πR
B. πR
C. 4πR
D. R

Solution

The distance traveled by the center of mass after one complete rotation is equal to the circumference of the wheel, which is 2πR.

Correct Answer: A — 2πR

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Q. A wheel of radius R rolls without slipping on a horizontal surface. If it rotates with an angular velocity ω, what is the linear velocity of the center of the wheel?

A. Rω
B. 2Rω
C. ω/R
D. R/ω

Solution

The linear velocity v of the center of the wheel is related to the angular velocity ω by the equation v = Rω.

Correct Answer: A — Rω

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Q. If a disc rolls without slipping on a flat surface, what is the relationship between its linear velocity v and angular velocity ω?

A. v = rω
B. v = 2rω
C. v = 1/2 rω
D. v = 3rω

Solution

For rolling without slipping, the linear velocity v is equal to the radius r times the angular velocity ω, hence v = rω.

Correct Answer: A — v = rω

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Q. If a hollow cylinder and a solid cylinder of the same mass and radius roll down the same incline, which one reaches the bottom first?

A. Hollow cylinder
B. Solid cylinder
C. Both reach at the same time
D. Depends on the angle of incline

Solution

The solid cylinder reaches the bottom first because it has a smaller moment of inertia compared to the hollow cylinder.

Correct Answer: B — Solid cylinder

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Q. If a hollow cylinder rolls down an incline, how does its acceleration compare to that of a solid cylinder?

A. Hollow cylinder accelerates faster
B. Solid cylinder accelerates faster
C. Both accelerate equally
D. Depends on the angle of incline

Solution

The solid cylinder has a lower moment of inertia compared to the hollow cylinder, thus it accelerates faster down the incline.

Correct Answer: B — Solid cylinder accelerates faster

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Q. If a hollow sphere and a solid sphere of the same mass and radius roll down the same incline, which one reaches the bottom first?

A. Hollow sphere
B. Solid sphere
C. Both reach at the same time
D. Depends on the angle of incline

Solution

The solid sphere has a smaller moment of inertia compared to the hollow sphere, thus it accelerates faster and reaches the bottom first.

Correct Answer: B — Solid sphere

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Q. If a hollow sphere rolls down an incline, how does its acceleration compare to that of a solid sphere?

A. Greater
B. Less
C. Equal
D. Depends on mass

Solution

The hollow sphere has a greater moment of inertia, resulting in less acceleration compared to the solid sphere.

Correct Answer: B — Less

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Q. If a rolling object has a mass m and radius R, what is the expression for its rotational kinetic energy?

A. (1/2)Iω^2
B. (1/2)mv^2
C. (1/2)mv^2/R^2
D. (1/2)mv^2 + (1/2)Iω^2

Solution

The rotational kinetic energy is given by (1/2)Iω^2, where I is the moment of inertia.

Correct Answer: A — (1/2)Iω^2

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Q. If a rolling object has a mass m and radius r, what is the expression for its total kinetic energy?

A. (1/2)mv^2
B. (1/2)mv^2 + (1/2)Iω^2
C. (1/2)mv^2 + (1/2)mr^2ω^2
D. (1/2)mv^2 + (1/2)(2/5)mr^2(ω^2)

Solution

The total kinetic energy of a rolling object is the sum of translational and rotational kinetic energy, which can be expressed as (1/2)mv^2 + (1/2)(2/5)mr^2(ω^2).

Correct Answer: D — (1/2)mv^2 + (1/2)(2/5)mr^2(ω^2)

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Q. If a rolling object has a radius of R and rolls with a speed v, what is its kinetic energy?

A. (1/2)mv^2
B. (1/2)mv^2 + (1/2)Iω^2
C. (1/2)mv^2 + (1/2)(1/2)mR^2(v/R)^2
D. None of the above

Solution

The total kinetic energy of a rolling object is the sum of translational and rotational kinetic energy, which simplifies to (1/2)mv^2 + (1/4)mv^2 = (3/4)mv^2.

Correct Answer: C — (1/2)mv^2 + (1/2)(1/2)mR^2(v/R)^2

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Q. If a rolling object has a radius R and rolls with an angular velocity ω, what is its linear velocity?

A. Rω
B. 2Rω
C. R/2ω
D. 3Rω

Solution

The linear velocity v of a rolling object is given by v = Rω.

Correct Answer: A — Rω

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Q. If a rolling object has a translational speed of v and a rotational speed of ω, what is the relationship between them for rolling without slipping?

A. v = ωR
B. v = 2ωR
C. v = ω/R
D. v = R/ω

Solution

For rolling without slipping, the relationship is v = ωR, where v is the translational speed and ω is the angular speed.

Correct Answer: A — v = ωR

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Q. If a solid cylinder rolls without slipping, what fraction of its total kinetic energy is translational?

A. 1/3
B. 1/2
C. 2/3
D. 1

Solution

For a solid cylinder, the total kinetic energy is KE_total = KE_translational + KE_rotational = (1/2)mv^2 + (1/2)(1/2)mR^2(ω^2). Since ω = v/R, the translational part is 2/3 of the total.

Correct Answer: C — 2/3

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Q. If a solid cylinder rolls without slipping, what is the ratio of its translational kinetic energy to its rotational kinetic energy?

A. 1:1
B. 2:1
C. 1:2
D. 3:1

Solution

For a solid cylinder, the translational kinetic energy (KE_trans) is (1/2)mv² and the rotational kinetic energy (KE_rot) is (1/2)(Iω²). The ratio KE_trans:KE_rot is 1:2.

Correct Answer: C — 1:2

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Q. If a solid disk rolls without slipping, what fraction of its total energy is translational at the bottom of an incline?

A. 1/4
B. 1/3
C. 1/2
D. 2/3

Solution

For a solid disk, the translational kinetic energy is 1/3 of the total kinetic energy when rolling without slipping.

Correct Answer: B — 1/3

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Q. If a solid sphere and a solid cylinder of the same mass and radius are released from rest at the same height, which will have a greater speed at the bottom?

A. Solid sphere
B. Solid cylinder
C. Both have the same speed
D. Depends on the mass

Solution

Both will have the same speed at the bottom due to conservation of energy, as they start from the same height.

Correct Answer: C — Both have the same speed

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Showing 31 to 60 of 71 (3 Pages)

Rolling Motion MCQ & Objective Questions

Understanding rolling motion is crucial for students preparing for school and competitive exams. This topic not only forms a significant part of the physics syllabus but also helps in developing a deeper understanding of mechanics. Practicing MCQs and objective questions on rolling motion can enhance your exam preparation, allowing you to tackle important questions with confidence and improve your overall scores.

What You Will Practise Here

Definition and characteristics of rolling motion
Difference between rolling motion and sliding motion
Key formulas related to rolling motion, including moment of inertia
Applications of rolling motion in real-life scenarios
Diagrams illustrating rolling motion concepts
Energy considerations in rolling motion
Common examples of rolling objects in physics

Exam Relevance

Rolling motion is a vital topic in various examinations, including CBSE, State Boards, NEET, and JEE. Students can expect questions that test their understanding of the principles of rolling motion, often presented in the form of numerical problems or conceptual MCQs. Familiarity with this topic can help you identify patterns in questions, such as those involving the calculation of velocities, accelerations, and energy transformations in rolling objects.

Common Mistakes Students Make

Confusing rolling motion with sliding motion, leading to incorrect application of formulas.
Neglecting the role of friction in rolling motion problems.
Misunderstanding the concept of moment of inertia and its impact on rolling objects.
Overlooking energy conservation principles when analyzing rolling motion scenarios.

FAQs

Question: What is the difference between rolling motion and sliding motion?
Answer: Rolling motion involves an object rotating about an axis while translating, whereas sliding motion occurs when an object moves without rotation.

Question: How does friction affect rolling motion?
Answer: Friction is essential for rolling motion as it prevents slipping and allows the object to roll smoothly.

Now is the time to boost your understanding of rolling motion! Dive into our practice MCQs and test your knowledge on this important topic. With consistent practice, you can master rolling motion and excel in your exams!

Rolling Motion

Rolling Motion MCQ & Objective Questions

What You Will Practise Here

Exam Relevance

Common Mistakes Students Make

FAQs

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