Explanation 1) Concept We can use the law of conservation of angular momentum and energy to find the angle θ 2) Formula i) L i = L f ii) P E = K E 3) Given Data i) m = 50 g ii) M = 100 g iii) h = 20 c m 4) Calculation First use conservation of energy to find velocity as follow m g h = 0.5 m v 2 So, v = 2 g h We can write the angular momentum before the collision is, L i = m v d Here d is the length of the rod from the point O, about which the rod would be rotating. Now conservation of angular momentum, L i = L f m v d = I r o d + m d 2 ω Rotational inertia of the rod is about the axis passing through its end can be written as, I = 1 3 M d 2 m v d = 1 3 M d 2 + m d 2 ω So ω = m d 2 g h M d 2 3 + m d 2 ω = m 2 g h d ( M 3 + m ) From trigonometry,

11th Edition

ISBN: 9781119306856

Author: Halliday

Publisher: WILEY

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Center of Gravity of a system

The centre of gravity is a property that is based on the geometry of a rigid body or any particle. It is described as an equilibrium point or a hypothetical location where the total weight of the body is concentrated.

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Chapter 11, Problem 66P

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θ through which the rod pivots about point O before momentarily stopping.

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Chapter 11, Problem 65P

Chapter 11, Problem 67P

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Chapter 11 Solutions

Fundamentals Of Physics - Volume 1 Only

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To Find θ through which the rod pivots about point O before momentarily stopping.

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To Find θ through which the rod pivots about point O before momentarily stopping.

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Chapter 11 Solutions

To Find

θ through which the rod pivots about point O before momentarily stopping.