EBK WEBASSIGN FOR KATZ'S PHYSICS FOR SC
EBK WEBASSIGN FOR KATZ'S PHYSICS FOR SC
1st Edition
ISBN: 9781337684651
Author: Katz
Publisher: VST
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Chapter 8, Problem 82PQ

(a)

To determine

The gravitational potential energy of the graph-Earth system at the grape’s initial position.

(a)

Expert Solution
Check Mark

Answer to Problem 82PQ

The gravitational potential energy of the graph-Earth system at the grape’s initial position is 6.47×103J .

Explanation of Solution

The grapes position at different heights is shown below.

EBK WEBASSIGN FOR KATZ'S PHYSICS FOR SC, Chapter 8, Problem 82PQ

Write the expression for the radius of bowl.

  r=d2                                                                                                                         (I)

Here, r is the radius of bowl, d is the diameter of the bowl.

Write the expression for the gravitational potential energy.

  U=mgh                                                                                                                  (II)

Here, U is the gravitational potential energy, m is the mass of grape, g is the acceleration due to gravity and h is the height of grape from bottom of bowl.

Conclusion:

Initially grape is resting at upper edge. Thus, initial height is equal to radius of bowl.

Substitute 44.0cm for d in equation (I) to get r.

  r=0.44cm2=0.220cm

Substitute 0.220cm for r, 9.81m/s2 for g and 3.00g for m in equation(II) to get potential energy at initial point.

  U1=(3.00g×1kg1000g)(9.81m/s2)(22.0cm×1m100cm)=6.47×103J

Here, U1 is the potential energy when the grape is at top of bowl.

Therefore, the gravitational potential energy of the graph-Earth system at the grape’s initial position is 6.47×103J .

(b)

To determine

The kinetic energy of the grape when it reaches the bottom of the bowl.

(b)

Expert Solution
Check Mark

Answer to Problem 82PQ

The kinetic energy of the grape when it reaches the bottom of the bowl is 6.47×103J .

Explanation of Solution

Take the bottom of the bowl as h=0 point.

Write conservation of energy equation as the grape moves from top of the bowl to bottom of bowl.

  U1+K1=U3+K3                                                                                                    (III)

Here, K1 is the kinetic energy at top of bowl, U3 is the potential energy at bottom of bowl and K3 is the kinetic energy at bottom of bowl.

Conclusion:

In problem it is given that initially the grape is at rest at upper edge of bowl. At bottom of bowl potential energy is zero, since h=0. Potential energy at upper edge of the ball is obtained as 6.47×103J.

Substitute 0J for K1 and 0J for U3 in equation (III) to get K3.

  U1+0J=0J+K3K3=U1

Substitute 6.47×103J for U1 in above equation to get K3.

  K3=6.47×103J

Therefore, the kinetic energy of the grape when it reaches the bottom of the bowl is 6.47×103J .

(c)

To determine

The speed of the grape when it reaches the bottom of the bowl.

(c)

Expert Solution
Check Mark

Answer to Problem 82PQ

The speed of the grape when it reaches the bottom of the bowl is 2.08m/s .

Explanation of Solution

Kinetic energy of the grape at bottom of bowl is obtained as 6.47×103J.

Write the expression for kinetic energy of grape.

  K3=12mv32

Here, m is the mass of grape and v3 is the velocity of the grape at bottom of bowl.

Rearrange above equation to get v3.

  v3=2K3m                                                                                                             (IV)

Conclusion:

Substitute 6.47×103J for K3 and 3.00g for m in equation (IV) to get K3.

  v3=2(6.47×103J)3.00g×1kg1000g=2.08m/s

Therefore, the speed of the grape when it reaches the bottom of the bowl is 2.08m/s .

(d)

To determine

The potential and kinetic energies of the grape when it reaches a point that is height h=15.0cm above the bottom of the bowl.

(d)

Expert Solution
Check Mark

Answer to Problem 82PQ

The potential energy of the grape when it reaches a point that is height h=15.0cm above the bottom of the bowl is 4.41×103J and the kinetic energy is 2.06×103J .

Explanation of Solution

Rewrite equation (I) to get potential energy at a height.

  U=mgh

Write conservation of energy equation as the grape moves from the top of the bowl to a height h=15.0cm above the bottom of the bowl.

  U1+K1=U2+K2                                                                                                   (V)

Here, U2 is the potential energy at height h=15.0cm of bowl and K2 is the kinetic energy at h=15.0cm of bowl.

Conclusion:

Substitute 9.81m/s2 for g, 15.0cm for h and 3.00g for m equation (I) to get potential energy at h=15.0cm.

  U2=(3.00g×1kg1000g)(9.81m/s2)(15.0cm×1m100cm)=4.41×103J

In problem it is given that initially the ball is at rest at upper edge of bowl. Kinetic energy is zero at top edge of bowl. At top edge of bowl potential energy is 6.47×103J.

Substitute 6.47×103J for U1, 0J for K1  and 4.41×103J for U2 in equation (V) to get K2.

  6.47×103J+0J=4.41×103J+K2K2=6.47×103J4.41×103J=2.06×103J

Therefore, the potential energy of the grape when it reaches a point that is height h=15.0cm above the bottom of the bowl is 4.41×103J and the kinetic energy is 2.06×103J .

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Chapter 8 Solutions

EBK WEBASSIGN FOR KATZ'S PHYSICS FOR SC

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