EBK PHYSICS FOR SCIENTISTS AND ENGINEER
EBK PHYSICS FOR SCIENTISTS AND ENGINEER
16th Edition
ISBN: 8220100546716
Author: Katz
Publisher: CENGAGE L
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Chapter 11, Problem 50PQ

In a laboratory experiment, an electron with a kinetic energy of 50.5 keV is shot toward another electron initially at rest (Fig. P11.50). (1 eV = 1.602 × 10−19 J) The collision is elastic. The initially moving electron is deflected by the collision.

  1. a. Is it possible for the initially stationary electron to remain at rest after the collision? Explain.
  2. b. The initially moving electron is detected at an angle of 40.0° from its original path. What is the speed of each electron after the collision?

Chapter 11, Problem 50PQ, In a laboratory experiment, an electron with a kinetic energy of 50.5 keV is shot toward another

FIGURE P11.50

(a)

Expert Solution
Check Mark
To determine

Whether it is possible for the initially stationary electron to remain at rest after the collision.

Answer to Problem 50PQ

It is not possible for the initially stationary electron to remain at rest after the collision.

Explanation of Solution

The elastic collision is characterized by the conservation of momentum as well as kinetic energy. For an elastic collision initial momentum of the system before collision should be equal to the momentum of the system after collision.

In the given situation, the initial momentum of the system in y direction is zero since the initially moving electron moves along the x axis and the other electron is at rest. This implies the momentum of the system in y direction after the collision also should be zero. But there is component of momentum in positive y direction for the initially moving electron after collision. This implies the net momentum of the two-electron system after collision in the y direction can be zero only if the electron which was initially at rest has an equal momentum in negative y direction after the collision. For this electron to have momentum, it must move after the collision.

Conclusion:

Thus, it is not possible for the initially stationary electron to remain at rest after the collision.

(b)

Expert Solution
Check Mark
To determine

The speed of each electron after the collision.

Answer to Problem 50PQ

The speed of initially moving electron after the collision is 1.02×108 m/s and that of the other electron is 8.55×107 m/s .

Explanation of Solution

The given situation is a two-dimensional elastic collision between two particles of equal mass with initial velocity for one of the particle equal to zero. For such a collision, the angle between the final velocities of the particles after the collision will be equal to 90° .

  θ1+θ2=90°

Here, θ1 is the angle electron 1 makes with the x axis and θ2 is the angle electron 2 makes with the x axis.

Rearrange the above equation for θ2 .

  θ2=90°θ1

It is given that the value of θ1 is 40° .

Substitute 40° for θ1 in the above equation to find the value of θ2 .

  θ2=90°40°=50°

Write the expression for the conservation of momentum in x direction.

  mev1i=mev1fx+mev2fx                                                                                               (I)

Here, me is the mass of the electron, v1i is the initial speed of the electron which is in the x direction, v1fx is the component of final velocity of the electron 1 in x direction and v2fx is the component of final velocity of the electron 2 in x direction.

Write the expression for v1fx .

  v1fx=v1fcosθ1

Here, v1f is the velocity of electron 1 after collision.

Substitute 40° for θ1 in the above equation to find the expression for of v1fx .

  v1fx=v1fcos40°                                                                                                      (II)

Write the expression for v2fx .

  v2fx=v2fcosθ2

Here, v2f is the velocity of electron 2 after collision.

Substitute 50° for θ2 in the above equation to find the expression for of v2fx .

  v2fx=v2fcos50°                                                                                                    (III)

Put equations (II) and (III) in equation (I).

  mev1i=mev1fcos40°+mev2fcos50°                                                                     (IV)

The momentum in y direction for the two-electron system before collision is zero.

Write the expression for the conservation of momentum in y direction.

  0=mev1fy+mev2fy                                                                                                (V)

Here, v1fy is the component of final velocity of the electron 1 in y direction and v2fy is the component of final velocity of the electron 2 in y direction.

Write the expression for v1fy .

  v1fy=v1fsinθ1

Substitute 40° for θ1 in the above equation to find the expression for of v1fy .

  v1fy=v1fsin40°                                                                                                     (VI)

Write the expression for v2fy .

  v2fy=v2fsinθ2

The negative sign is due to the fact that the electron 2 moves in negative y direction.

Substitute 50° for θ2 in the above equation to find the expression for of v2fy .

  v2fy=v2fsin50°                                                                                                  (VII)

Put equations (VI) and (VII) in equation (V) and rearrange it for v1f .

  mev1fsin40°=mev2fsin50°v1f=v2fsin50°sin40°                                                                                (VIII)

Put the above equation in equation (IV) and rearrange it for v2f .

  mev1i=me(v2fsin50°sin40°)cos40°+mev2fcos50°v1i=v2f(sin50°sin40°cos40°+cos50°)=1.56v2fv2f=0.643v1i                                                  (IX)

Put equation (IX) in equation (VIII).

  v1f=(0.643v1i)sin50°sin40°=0.766v1i                                                                                            (X)

Write the equation for the initial kinetic energy of electron 1.

  K=12mev1i2

Here, K is the initial kinetic energy of electron 1.

Rewrite the above equation for v1i .

  v1i2=2Kmev1i=2Kme                                                                                                              (XI)

Conclusion:

It is given that the initial kinetic energy of electron 1 is 50.5 keV. The mass of the electron is 9.11×1031 kg .

Substitute 50.5 keV for K and 9.11×1031 kg for me in equation (XI) to find v1i .

  v1i=2(50.5 keV1.602×1016 J1 keV)9.11×1031 kg=1.33×108 m/s

Substitute 1.33×108 m/s for v1i in equation (X) to find the value of v1f .

  v1f=0.766(1.33×108 m/s)=1.02×108 m/s

Substitute 1.33×108 m/s for v1i in equation (IX) to find the value of v2f .

  v2f=0.643(1.33×108 m/s)=8.55×107 m/s

Therefore, the speed of initially moving electron after the collision is 1.02×108 m/s and that of the other electron is 8.55×107 m/s .

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Chapter 11 Solutions

EBK PHYSICS FOR SCIENTISTS AND ENGINEER

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