Explanation Introduction: The restoring force which is exerted by the Earth on an object is directly proportional to the mass of the Earth and the mass of the object. And the restoring force is inversely proportional to the square of the distance between them. The restoring force that Earth exerts on an object is written as, F = G m inside r m R 2 Here, G represents the universal gravitational constant, m inside r represents the mass of the Earth inside the radius r , and R represents the distance between the center of the Earth and the object. The object is on the surface of the Earth, therefore, the distance between the center of the Earth and the object will be the radius of the Earth. It is written as, R = r Here, R represents the distance between the center of the Earth and the object and r represents the radius of the Earth. The expression for the restoring force is also written in terms of force constant as, F = k r Here, k represents the force constant and r represents the radius of the sphere inside the Earth. The expression for the time period of oscillation is written as, T = 2 π m k Here, m represents the mass and k represents the restoring force constant. Explanation: Reason for the correct option: Recall the expression for the volume of the Earth. V s = ( 4 3 ) π r 3 Here, r represents the radius of the Earth. Recall the expression for the mass of the Earth. m = ρ V s Here, ρ represents the density of the Earth and V s represents the volume of the the Earth. Rearrange the above expression by substituting V s = ( 4 3 ) π r 3 . m inside r = ρ ( ( 4 3 ) π r 3 ) = ( 4 3 ) π r 3 ρ Recall the expression for the restoring force that Earth exerts on an object. F = G m inside r m R 2 Since, the object is on the surface of the Earth, therefore, the distance between the center of the earth and the object will be the radius of the Earth. It is written as, R = r Now, recall the expression for the restoring force as, F = G m inside r m r 2 Substitute, m inside r = ( 4 3 ) π r 3 ρ in the above expression

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Author: ETKINA

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Question

Chapter 10, Problem 74RPP

To determine

The expression that represents the period T

for one oscillation from Earth’s surface through the center, to the other side, and then back again, from the following options:

a. 2π( 3 G4πρ ) 1 2

b. 2π( G4πρ 3 ) 1 2

c. 2π( 3m G4πρ ) 1 2

d. 2π( mG4πρ 3 ) 1 2

e. 2π( m k ) 1 2

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Chapter 10, Problem 73RPP

Chapter 10, Problem 75RPP

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Ch. 10 - Review Question 10.1 Can we say that the period of...Ch. 10 - Review Question 10.2 The velocity of an object...Ch. 10 - Review Question 10.3 What will happen to the...Ch. 10 - Review Question 10.4 The period of vibration of a...Ch. 10 - Review Question 10.5 Your grandfathers pendulum...Ch. 10 - Why was it important to assume that the springs...Ch. 10 - Review Question 10.7 What features of damped...Ch. 10 - Review Question 10.8 Describe the phenomenon of...Ch. 10 - 1. What are the features that make vibrational...Ch. 10 - 2. What does it mean if the amplitude of an...

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Solution Summary: The author explains that the restoring force exerted by Earth on an object is directly proportional to the mass of the Earth and the distance between them.

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The expression that represents the period T for one oscillation from Earth’s surface through the center, to the other side, and then back again, from the following options: a. 2π( 3 G4πρ ) 1 2 b. 2π( G4πρ 3 ) 1 2 c. 2π( 3m G4πρ ) 1 2 d. 2π( mG4πρ 3 ) 1 2 e. 2π( m k ) 1 2

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Chapter 10 Solutions

The expression that represents the period T

for one oscillation from Earth’s surface through the center, to the other side, and then back again, from the following options:

a. 2π( 3 G4πρ ) 1 2

b. 2π( G4πρ 3 ) 1 2

c. 2π( 3m G4πρ ) 1 2

d. 2π( mG4πρ 3 ) 1 2

e. 2π( m k ) 1 2