Physics for Scientists and Engineers with Modern Physics
Physics for Scientists and Engineers with Modern Physics
10th Edition
ISBN: 9781337553292
Author: Raymond A. Serway, John W. Jewett
Publisher: Cengage Learning
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Chapter 38, Problem 54CP

(a)

To determine

To show: The acceleration of the particle in the x direction is a=dudt=qEm(1u2c2)3/2

(a)

Expert Solution
Check Mark

Answer to Problem 54CP

The acceleration of the particle in the x direction is a=dudt=qEm(1u2c2)3/2 .

Explanation of Solution

The formula to calculate the relative momentum is,

p=mu1(u/c)2

Here,

m is the mass of the electric charge.

c is the speed of the light.

u is the speed of the electric charge.

The formula to calculate the force on the electric charge is,

F=qE

Here,

q is the charge of the electric charge.

E is the magnitude of the electric field.

The formula to calculate the Force due to motion is,

F=dpdt

The force on the electric charge due to motion must be equal to that of the force due to electric field.

Substitute qE for F in above equation to find dpdt .

qE=dpdt

Substitute mu1(u/c)2 for p in above equation.

qE=ddt(mu1(u/c)2)qE=ddt[mu(1u2c2)12]qE=m(1u2c2)12dudt+12mu(1u2c2)32(2uc2)dudtqEm=dudt[1(1(u/c)2)32]

Further solve the above equation.

dudt=qEm(1u2c2)3/2 (1)

The formula to calculate the acceleration is,

a=dudt

Substitute a for dudt in equation (1).

a=dudt=qEm(1u2c2)3/2

Conclusion

Therefore, the acceleration of the particle in the x direction is a=dudt=qEm(1u2c2)3/2 .

(b)

To determine

The significance of the dependence of the acceleration on the speed.

(b)

Expert Solution
Check Mark

Answer to Problem 54CP

The significance of the dependence of the acceleration on the speed is that when the speed of the charge is very small as compared to that of the speed of light the relative expression is transformed to the classical expression.

Explanation of Solution

The formula to calculate the acceleration of the charge is,

a=dudt=qEm(1u2c2)3/2

As the speed of charge approaches to the speed of light, the acceleration approaches to zero.

When the speed of the charge is very small as compared to that of the speed of the light the above equation can be transformed.

a=dudt=qEm

So the relative expression is transformed to the classical expression when the speed of the charge is very small as compared to that of the speed of the light.

Conclusion

Therefore, the significance of the dependence of the acceleration on the speed is that when the speed of the charge is very small as compared to that of the speed of light the relative expression is transformed to the classical expression.

(c)

To determine

The speed and the position of the charge particle at time t .

(c)

Expert Solution
Check Mark

Answer to Problem 54CP

The speed of the charge particle at time t is qEctm2c2+q2E2t2 and the position of the charge particle at time t is cqE(m2c2+q2E2t2mc) .

Explanation of Solution

The formula to calculate the acceleration of the charge is,

dudt=qEm(1u2c2)3/2

Integrate the above equation from velocity 0 to v and time 0 to t to find the total velocity.

0udu(1u2c2)3/2=0tqEmdtu(1u2c2)1/2=qEtmu2=(qEtm)2(1u2c2)u=qEctm2c2+q2E2t2

Thus the speed of the particle at time t is qEctm2c2+q2E2t2 .

The formula to calculate the position of the particle is,

dxdt=u

Substitute qEctm2c2+q2E2t2 for u in above equation to find the value of x .

dxdt=qEctm2c2+q2E2t2

Integrate the above equation from position 0 to x and time 0 to t to find the final position.

0xdx=0tqEctm2c2+q2E2t2dtx=cqE[m2c2+q2E2t2]0t=cqE(m2c2+q2E2t2mc)

Conclusion

Therefore, the speed of the charge particle at time t is qEctm2c2+q2E2t2 and the position of the charge particle at time t is cqE(m2c2+q2E2t2mc) .

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