Physics for Scientists and Engineers, Volume 1, Chapters 1-22
Physics for Scientists and Engineers, Volume 1, Chapters 1-22
8th Edition
ISBN: 9781439048382
Author: Raymond A. Serway, John W. Jewett
Publisher: Cengage Learning
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Chapter 25, Problem 25.55AP

Review. From a large distance away, a particle of mass 2.00 g and charge 15.0 μC is fired at 21.0î m/s straight toward a second particle, originally stationary but free to move, with mass 5.00 g and charge 8.50 μC. Both particles are constrained to move only along the x axis.

  1. (a) At the instant of' closest approach, both particles will be moving at the same velocity. F'ind this velocity.
  2. (b) Find the distance of closest approach. After the interaction, the particles will move far apart again. At this time, find the velocity of (c) the 2.00-g particle and (d) the 5.00-g particle.

(a)

Expert Solution
Check Mark
To determine

The velocity at the instant when the both particle moves with same velocity.

Answer to Problem 25.55AP

The velocity at the instant of closest approach when the both particle moves with same velocity is 6.00i^m/s .

Explanation of Solution

Given info: The mass of first particle is 2.00g , charge of first particle is 15.0μC , velocity of the first particle is 21.0i^m/s , mass of second particle is 5.00g and charge of second particle is 8.50μC .

The momentum is conserved of an isolated system.

m1v1i+m2v2i=m1v1f+m2v2f

Here,

m1 is the mass of the first particle.

v1i is the initial velocity of the first particle.

m2 is the mass of the second particle.

v2i is the initial velocity of the second particle.

Substitute 0 for v2i , v for v1i , vc for v1f and vc v2f for in above equation.

m1vi^+0=m1vci^+m2vci^vc=(m1vm1+m2)

Substitute 2.00g for m1 , 21.0i^m/s for v and 5.00g for m2 in above equation.

vc=(2.00g×21.0i^m/s2.00g+5.00g)=6.00i^m/s

Conclusion:

Therefore, the velocity at the instant of closest approach when the both particle moves with same velocity is 6.00i^m/s .

(b)

Expert Solution
Check Mark
To determine

The closet distance.

Answer to Problem 25.55AP

The closet distance is 3.64m .

Explanation of Solution

Given info: The mass of first particle is 2.00g , charge of first particle is 15.0μC , velocity of the first particle is 21.0i^m/s , mass of second particle is 5.00g and charge of second particle is 8.50μC .

From part (a) the value of vc is (m1vm1+m2) .

Write the expression for initial the kinetic energy of first particle.

k1i=12m1v1i2

Here,

m1 is the mass of the first particle.

v1i is the initial velocity of the first particle.

k1i is the initial kinetic energy of the first particle.

Write the expression for final the kinetic energy of first particle.

k1f=12m1vc2

Here,

vc is the final velocity of the first particle.

k1f is the final kinetic energy of the first particle.

Write the expression for initial the kinetic energy of second particle.

k2i=12m2v2i2

Here,

m2 is the mass of the second particle.

v2i is the initial velocity of the second particle.

k2i is the initial kinetic energy of the second particle.

Write the expression for final the kinetic energy of second particle.

k2f=12m2vc2

Here,

vc is the final velocity of the second particle.

k2f is the final kinetic energy of the second particle.

Total initial kinetic energy is given by,

ki=k1i+k2i

Substitute 12m1v1i2 for k1i and 12m2v2i2 for k2i in above equation.

ki=12m1v1i2+12m2v2i2

Substitute 0 for v2i and v for v1i in above equation.

ki=12m1v2+12m2(0)2=12m1v2

Total final kinetic energy is given by,

kf=k1f+k2f

Substitute 12m1vc2 for k1i and 12m2vc2 for k2i in above equation.

kf=12m1vc2+12m2vc2=12(m1+m2)vc2

The initial electric potential energy is 0 .

Ui=0

Here,

Ui is the initial electric potential energy.

The final electric potential energy is expressed as,

Uf=keq1q2rc

Here,

ke is the coulomb’s constant.

rc is the closest distance.

q1 is first charge.

q2 is the second charge.

Uf is the final electric potential energy.

The energy is conserved within the isolated system.

ki+Ui=kf+Uf

Substitute 12m1v2 for ki , 0 for Ui , 12(m1+m2)vc2 for kf and keq1q2rc for Uf in above equation.

12m1v2+0=12(m1+m2)vc2+keq1q2rc

Substitute (m1vm1+m2) for vc in above equation.

12m1v2+0=12(m1+m2)((m1vm1+m2))2+keq1q2rcm1m2v2=2keq1q2(m1+m2)rcrc=2keq1q2(m1+m2)m1m2v2

Substitute 8.99×109Nm2/C2 for ke , 2.00g for m1 , 5.00g for m2 , 21.0i^m/s for v , 15.0μC for q1 and 8.50μC for q2 in above equation.

rc=[2(8.99×109Nm2/C2)×((15.0μC(106C1μC))(8.50μC(106C1μC))(2.00g(103kg1g)+5.00g(103kg1g))(2.00g(103kg1g))(5.00g(103kg1g))(21.0i^m/s)2)]=3.638m3.64m

Conclusion:

Therefore, the closet distance is 3.64m .

(c)

Expert Solution
Check Mark
To determine

The velocity of the particle of mass 2.00g .

Answer to Problem 25.55AP

The velocity of the particle of mass 2.00g is 9.00i^m/s .

Explanation of Solution

Given info: The mass of first particle is 2.00g , charge of first particle is 15.0μC , velocity of the first particle is 21.0i^m/s , mass of second particle is 5.00g and charge of second particle is 8.50μC .

The expression for the relative velocity is,

v1iv2i=v2fv1f

Substitute 0 for v2i and v for v1i in above equation.

v0=v2fv1fv2f=v+v1f

The overall elastic collision is described by the conservation of the momentum.

m1v1i+m2v2i=m1v1f+m2v2f

Substitute 0 for v2i and v for v1i in above equation.

m1vi^+0=m1v1fi^+m2v2fi^m1v=m1v1f+m2v2f

Substitute v+v1f for v2f in above equation.

m1v=m1v1f+(v+v1f)m2m1v=m1v1f+m2v+m2v1fv1f=(m1m2m1+m2)v

Substitute 2.00g for m1 , 5.00g for m2 and 21.0i^m/s for v in above equation.

v1f=(2.00g5.00g2.00g+5.00g)(21.0i^m/s)=9.00i^m/s

Conclusion:

Therefore, the velocity of the particle of mass 2.00g is 9.00i^m/s .

(d)

Expert Solution
Check Mark
To determine

The velocity of the particle of mass 5.00g .

Answer to Problem 25.55AP

The velocity of the particle of mass 5.00g is 12.0i^m/s .

Explanation of Solution

From part (c) the value of v1f is (m1m2m1+m2)v .

From part (c) the expression for v2f is,

v2f=v+v1f

Substitute (m1m2m1+m2)v for v1f in above equation.

v2f=v+(m1m2m1+m2)v=(2m1m1+m2)v

Substitute 2.00g for m1 , 5.00g for m2 and 21.0i^m/s for v in above equation.

v2f=(2×2.00g2.00g+5.00g)21.0i^m/s=12.0i^m/s

Conclusion:

Therefore, the velocity of the particle of mass 5.00g is 12.0i^m/s .

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