Physics For Scientists And Engineers: Foundations And Connections, Extended Version With Modern Physics
Physics For Scientists And Engineers: Foundations And Connections, Extended Version With Modern Physics
1st Edition
ISBN: 9781305259836
Author: Debora M. Katz
Publisher: Cengage Learning
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Chapter 11, Problem 51PQ

In Figure P11.51, a cue ball is shot toward the eight-ball on a pool table. The cue ball is shot at the eight-ball with a speed of 8.00 m/s in a direction 30.0° from the y axis. Both balls have the same mass of 0.170 kg. After the balls undergo an elastic collision, the eight-ball travels in the negative x direction into the side pocket. What is the velocity of the cue ball after this collision?

Chapter 11, Problem 51PQ, In Figure P11.51, a cue ball is shot toward the eight-ball on a pool table. The cue ball is shot at

FIGURE P11.51

Expert Solution & Answer
Check Mark
To determine

The velocity of the cue ball after the collision.

Answer to Problem 51PQ

The velocity of the cue ball after the collision is 6.93j^m/s_.

Explanation of Solution

Given that the speed of the cue ball is 8.00m/s in a direction 30.0° from the y axis, and the mass of both the balls are 0.170kg. The diagrammatic representation of the situation is shown in Figure P11.51.

From the given Figure, deduce the x and y components of the initial velocity of the cue ball.

  v1iy=v1cosθ                                                                                                         (I)

  v1ix=v1sinθ                                                                                                       (II)

Here, v1iy is the y component of the initial velocity of the cue ball, v1ix is the x component of the initial velocity of the cue ball, and θ is the angle made by the cue ball’s velocity vector with the x axis, and v1 is the speed of the cue ball.

Write the expression for the momentum conservation along x and y directions in the given collision.

  m1v1ix+m2v2ix=m1v1fx+m2v2fx                                                                              (III)

  m1v1iy+m2v2iy=m1v1fy+m2v2fy                                                                            (IV)

Here, m1 is the mass of the cue ball, m2 is the mass of the eight ball, v2ix is the x component of the initial velocity of the eight ball, v2iy is the y component of the initial velocity of the eight ball, v1fx is the x component of the final velocity of the cue ball, v2fx is the x component of the final velocity of the eight ball, v2fx is the x component of the final velocity of the eight ball, and v2fy is the y component of the final velocity of the eight ball

Since the eight ball has no final y velocity, the y momentum (and hence velocity) of the cue ball remains unchanged in the collision. Moreover, the masses of the balls are equal. Thus, equation (III) and (IV) can be reduced to,

  v1ix=v1fx+v2fx                                                                                                      (V)

  v1iy=v1fy                                                                                                               (VI)

Apply the conservation of kinetic energy to the collision process.

  12mv1i2=12mv2f2+12mv1f2                                                                                    (VII)

Reduce equation (VII).

  12v1i2=12mv2fx2+12m(v1fx2+v1fy2)v1i2=v2fx2+v1fx2+v1fy2                                                                         (VIII)

Conclusion:

Substitute 8.00m/s for v1, 30.0° for θ in equation (I) to find v1iy.

  v1iy=(8.00m/s)cos30.0°=6.93m/s

Substitute 8.00m/s for v1, 30.0° for θ in equation (II) to find v1ix.

  v1ix=(8.00m/s)sin30.0°=4.00m/s

Substitute 4.00m/s for v1ix in equation (V) and solve for v1fx

  4.00m/s=v1fx+v2fxv1fx=4.00m/sv2fx                                                                                (IX)

Substitute 6.93m/s for v1iy in equation (VI).

  6.93m/s=v1fy                                                                                                      (X)

Substitute 8.00m/s for v1i, and 6.93m/s for v1iy in equation (VIII) and reduce.

  (8.00m/s)2=v2fx2+v1fx2+(6.93m/s)216.0m2/s2=v2fx2+v1fx2                                                                  (XI)

Use equation (IX) in (XI) and solve for v2fx.

  16.0m2/s2=v2fx2+(4.00m/sv2fx)22v2fx2+(8.00m/s)v2fx=0v2fx=4.00m/sorv2fx=0

The solution for v2fx that is consistent with the problem is v2fx=4.00m/s.

Substitute 4.00m/s for v2fx in equation (XI) and solve for v1fx.

  16.0m2/s2=(4.00m/s)2+v1fx2v1fx=(16.0m2/s2)(4.00m/s)2=0.00m/s

Write the expression for the velocity of the cue ball after the collision.

  v1f=v1fxi^+v1fyj^                                                                                                 (XII)

Substitute 0.00m/s for v1fx, and 6.93m/s for v1fy in equation (XII) to find v1f.

  v1f=(0.00m/s)i^+(6.93m/s)j^=6.93j^m/s

Therefore, the velocity of the cue ball after the collision is 6.93j^m/s_.

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Chapter 11 Solutions

Physics For Scientists And Engineers: Foundations And Connections, Extended Version With Modern Physics

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