Explanation 1) Concept: We can use the expression of angular momentum in terms of rotational inertia and angular velocity . We can find the mass of each disk by using the expression of density. All disks are connected by the same belt at the rim as well as its hub; hence their linear velocity will be the same. We use the expression of relation between linear velocity, angular velocity and their radius. 2) Formulae: i) v = R ω ii) I = 1 2 M R 2 iii) ρ = M V iv) L = I ω 3) Given: i) The disk A has radius R ii) Hub of disk A has radius 0.5000 R iii) The disk B has radius R B = 0.2500 R iv) The disk C has radius R c = 2.000 R v) Density of disk B and disk C is same as ρ 4) Calculations: The ratio of the magnitude of the angular momentum of disk C to that of disk B : The linear speed at the rim of disk A must equal the linear speed at the rim of disk C . v A = v C R ω A = 2.000 R ω C ω A = 2.000 ω C … ( 1 ) The linear speed at the hub of disk A must equal the linear speed at the rim of disk B v A = v B 0.5000 R ω A = 0.2500 R ω B ω A = 1 2 ω B … ( 2 ) From equations (1) and (2) as 2.000 ω C = 1 2 ω B ω B = 4 ω C The angular momenta depend on their angular velocities as well as their moment of inertia

10th Edition

ISBN: 9781118230725

Author: David Halliday, Robert Resnick, Jearl Walker

Publisher: Wiley, John & Sons, Incorporated

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Chapter 11, Problem 36P

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The ratio of the magnitude of the angular momentum of disk C to that of disk B

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Chapter 11, Problem 35P

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Chapter 11 Solutions

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The ratio of the magnitude of the angular momentum of disk C to that of disk B

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Chapter 11 Solutions

To Find:

The ratio of the magnitude of the angular momentum of disk C to that of disk B