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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Question
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Chapter 20, Problem 6PQ

(a)

To determine

The average velocity of the particles.

(a)

Expert Solution
Check Mark

Answer to Problem 6PQ

The average velocity of the particles is (3.1i^1.1j^0.02k^)m/s.

Explanation of Solution

Write the equation for the average velocity in the x direction for the particles.

    (vx)av=v1x+v2x+v3x+v4x+v5x5                                                                     (I)

Here, (vx)av is the average velocity in the x direction for the particles, v1x is the x component of the first particle, v2x is the x component of the second particle, v3x is the x component of the third particle, v4x is the x component of the fourth particle and v5x is the x component of the fifth particle.

Write the equation for the average velocity in the y direction for the particles.

    (vy)av=v1y+v2y+v3y+v4y+v5y5                                                                    (II)

Here, (vy)av is the average velocity in the y direction for the particles, v1y is the y component of the first particle, v2y is the y component of the second particle, v3y is the y component of the third particle, v4y is the y component of the fourth particle and v5y is the y component of the fifth particle.

Write the equation for the average velocity in the z direction for the particles.

    (vz)av=v1z+v2z+v3z+v4z+v5z5                                                                     (III)

Here, (vx)av is the average velocity in the z direction for the particles, v1z is the z component of the first particle, v2z is the z component of the second particle, v3z is the z component of the third particle, v4z is the z component of the fourth particle and v5z is the z component of the fifth particle.

Write the equation for the average velocity of the particles.

    vav=(vx)avi^+(vy)avj^+(vz)avk^                                                                  (IV)

Conclusion:

Substitute 3.4m/s for v1x, 2.4m/s for v2x, 0.4m/s for v3y, 9.2m/s for v4y and 0.9m/s for v5y in equation (I) to find (vx)av.

  (vx)av=3.4m/s+2.4m/s0.4m/s+9.2m/s+0.9m/s5=3.1m/s

Substitute 5.6m/s for v1y, 6.6m/s for v2y, 1.6m/s for v3y, 9.8m/s for v4y and 3.6m/s for v5y in equation (II) to find (vy)av.

  (vy)av=5.6m/s6.6m/s+1.6m/s9.8m/s+3.6m/s5=1.1m/s

Substitute 6.7m/s for v1z, 3.7m/s for v2z, 10.7m/s for v3z, 3.6m/s for v4z and 4.0m/s for v5z in equation (III) to find (vz)av.

  (vz)av=6.7m/s3.7m/s10.7m/s+3.6m/s+4.0m/s5=0.02m/s

Substitute 3.1m/s for (vx)av, 1.1m/s for (vy)av and 0.02m/s for (vz)av in equation (IV) to find vav.

    vav=3.1m/si^1.1m/sj^0.02m/sk^=(3.1i^1.1j^0.02k^)m/s

Thus, the average velocity of the particles is (3.1i^1.1j^0.02k^)m/s.

(b)

To determine

The average speed of the particles.

(b)

Expert Solution
Check Mark

Answer to Problem 6PQ

The average speed of the particles is 9.5m/s.

Explanation of Solution

Write the equation for the speedof the first particle.

    v1=(v1x)2+(v1y)2+(v1z)2                                                                  (V)

Write the equation for the average speed.

    vav=v1+v2+v3+v4+v55                                                                                (VI)

Conclusion:

Substitute 3.4m/s for v1x, 5.6m/s for v1y, 6.7m/s for v1z in equation (V) to find v1.

  v1=(3.4m/s)2+(5.6m/s)2+(6.7m/s)2=9.4m/s

Similarly, calculate the speed of the second particle.

    v2=7.9m/s

Calculate the speed of the third particle.

    v3=10.8m/s

Calculate the speed of the fourth particle.

    v4=13.9m/s

Calculate the speed of the fifth particle.

    v4=5.5m/s

Substitute 9.4m/s for v1, 7.9m/s for v2, 10.8m/s for v3, 13.9m/s for v4 and 5.5m/s for v5 in equation (VI) to find vav.

    vav=9.4m/s+7.9m/s+10.8m/s+13.9m/s+5.5m/s5=9.5m/s

Thus, the average speed of the particles is 9.5m/s.

(c)

To determine

The rms speed of the particles.

(c)

Expert Solution
Check Mark

Answer to Problem 6PQ

The rms speed of the particles is 9.9m/s.

Explanation of Solution

Write the equation for the rms speed of the particles.

    vrms=1Nj=1Nvj2                                                                               (VII)

Conclusion:

Substitute the values for the speeds of the particles in equation (VII) to find vrms.

  vrms=15[(9.4m/s)2+(7.9m/s)2+(10.8m/s)2+(13.9m/s)2+(5.5m/s)2]=9.9m/s

Thus, the rms speed of the particles is 9.9m/s.

(d)

To determine

Compare the speeds of the particles.

(d)

Expert Solution
Check Mark

Answer to Problem 6PQ

The rms speed is greater than the average speed.

Explanation of Solution

Write the equation for the magntide of the average velocity.

    |vavg|=(vav)x2+(vav)y2+(vav)z2                                                             (VIII)

Here, |vavg| is the magntide of the average velocity

Conclusion:

Susbtitute 3.1m/s for (vav)x, 1.1m/s for (vav)y and 0.20m/s for (vav)y to find |vavg|.

  |vavg|=(3.1m/s)2+(1.1m/s)2+(0.20m/s)2=3.3m/s

The value of rms speed is greater than the mahnitude of the average velocity. This is becauses, in calculationg the average velocity, the particles moving in the opposite direction is also considered.

Thus, the rms speed is greater than the average speed.

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Chapter 20 Solutions

EBK PHYSICS FOR SCIENTISTS AND ENGINEER

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