The total kinetic energy before collision in terms of m 1 , m 2 and p 1 , the total kinetic energy after collision in terms of m 1 , m 2 and p ′ 1 and the situation for p ′ 1 = + p 1 .

Question

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Answer 1

Question

Chapter 8, Problem 91P

To determine

The total kinetic energy before collision in terms of m1 ,m2 and p1 , the total kinetic energy after collision in terms of m1 ,m2 and p′1 and the situation for p′1=+p1 .

Expert Solution & Answer

Answer to Problem 91P

The total kinetic energy before collision in terms of m1 ,m2 and p1 is (K.E)I=p122(1m1+1m2) , The total kinetic energy after collision in terms of m1 ,m2 and p′1 is (K.E)F=p′122(1m1+1m2) . If p′1=−p1 , then particle collides with each other and rebounds back and have same speed. The situation p′1=+p1 can only occur if particle does not collide, but they pass by each other.

Explanation of Solution

Given:

The mass of particle 1 is m1 .

The mass of particle 2 is m2 .

Formula Used:

The expression for conservation of momentum is given by,

p′1+p′2=pcm

The expression for kinetic energy before collision is given by,

(K.E)I=12m1v12+12m2v22

The expression for kinetic energy after collision is given by,

(K.E)F=12m1v′12+12m2v′22

The expression for conservation of energy is,

(K.E)I=(K.E)F

Calculation:

The expression for conservation of momentum is calculated as,

p′1+p′2=pcmp′1+p′2=0p′2=−p′1

The expression for kinetic energy before collision is calculated as,

(K.E)I=12m1v12+12m2v22=12m1v12⋅m1m1+12m2v22⋅m2m2=m12v122m1+m12v222m2=p122m1+p222m2

Further simplify the above,

(K.E)I=p122m1+ ( − p 1 )22m2=p122m1+p122m2(K.E)I=p122(1 m 1 +1 m 2 )

The expression for kinetic energy after collision is calculated as,

(K.E)F=12m1v′12+12m2v′22=12m1v′12⋅m1m1+12m2v′22⋅m2m2=m12 v ′122m1+m12 v ′222m2= p ′122m1+ p ′222m2

Further simplify the above,

(K.E)F= p ′122m1+ ( − p ′ 1 )22m2= p ′122m1+ p ′122m2(K.E)F= p ′122(1 m 1 +1 m 2 )

The expression for conservation of energy is calculated as,

(K.E)F=(K.E)I p ′122(1 m 1 +1 m 2 )=p122(1 m 1 +1 m 2 )p′12=p12p′1=±p1

Conclusion:

Therefore, the total kinetic energy before collision in terms of m1 ,m2 and p1 is. (K.E)I=p122(1m1+1m2) , The total kinetic energy after collision in terms of m1 ,m2 and p′1 is (K.E)F=p′122(1m1+1m2) . If p′1=−p1 , then particle collides with each other and rebounds back and have same speed. The situation p′1=+p1 can only occur if particle does not collide, but they pass by each other.

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A particle with mass mA is struck head-on by another particle with mass mB that isinitially moving at speed v0 . The collision is elastic.(a) What percentage of the original energy does each particle have after the collision?(b) For what values, if any, of the mass ratio mA /mB is the original kinetic energy sharedequally by the two particles after the collision?

A particle with mass mA is struck head-on by another particle with mass mB that is initially moving at speed v0. The collision is elastic. (a) What percentage of the original energy does each particle have after the collision? (b) For what values, if any, of the mass ratio mA/mB is the original kinetic energy shared equally by the two particles after the collision?

Consider two objects/particles: Object 1 has mass 3m and speed v and Object 1 has mass 2m and speed 2v, respectively. In each of the three different scenarios, the objects collide inelastically and stick together after the collision. Scenario A: The objects move toward each other and collide head-on. Scenario B: Object 2m chases Object 3m and collides with from behind. Scenario C: The objects move at right angles before the collision. Rank these three scenarios from highest to lowest speed after the collision. (Circle ONLY ONE answer) a. B>A>C b. C>A>B c. C>B>A d. B>C>A e. A>B>C f. A>C>B

Answer 2

Question

Chapter 8, Problem 91P

To determine

The total kinetic energy before collision in terms of m1 ,m2 and p1 , the total kinetic energy after collision in terms of m1 ,m2 and p′1 and the situation for p′1=+p1 .

Expert Solution & Answer

Answer to Problem 91P

The total kinetic energy before collision in terms of m1 ,m2 and p1 is (K.E)I=p122(1m1+1m2) , The total kinetic energy after collision in terms of m1 ,m2 and p′1 is (K.E)F=p′122(1m1+1m2) . If p′1=−p1 , then particle collides with each other and rebounds back and have same speed. The situation p′1=+p1 can only occur if particle does not collide, but they pass by each other.

Explanation of Solution

Given:

The mass of particle 1 is m1 .

The mass of particle 2 is m2 .

Formula Used:

The expression for conservation of momentum is given by,

p′1+p′2=pcm

The expression for kinetic energy before collision is given by,

(K.E)I=12m1v12+12m2v22

The expression for kinetic energy after collision is given by,

(K.E)F=12m1v′12+12m2v′22

The expression for conservation of energy is,

(K.E)I=(K.E)F

Calculation:

The expression for conservation of momentum is calculated as,

p′1+p′2=pcmp′1+p′2=0p′2=−p′1

The expression for kinetic energy before collision is calculated as,

(K.E)I=12m1v12+12m2v22=12m1v12⋅m1m1+12m2v22⋅m2m2=m12v122m1+m12v222m2=p122m1+p222m2

Further simplify the above,

(K.E)I=p122m1+ ( − p 1 )22m2=p122m1+p122m2(K.E)I=p122(1 m 1 +1 m 2 )

The expression for kinetic energy after collision is calculated as,

(K.E)F=12m1v′12+12m2v′22=12m1v′12⋅m1m1+12m2v′22⋅m2m2=m12 v ′122m1+m12 v ′222m2= p ′122m1+ p ′222m2

Further simplify the above,

(K.E)F= p ′122m1+ ( − p ′ 1 )22m2= p ′122m1+ p ′122m2(K.E)F= p ′122(1 m 1 +1 m 2 )

The expression for conservation of energy is calculated as,

(K.E)F=(K.E)I p ′122(1 m 1 +1 m 2 )=p122(1 m 1 +1 m 2 )p′12=p12p′1=±p1

Conclusion:

Therefore, the total kinetic energy before collision in terms of m1 ,m2 and p1 is. (K.E)I=p122(1m1+1m2) , The total kinetic energy after collision in terms of m1 ,m2 and p′1 is (K.E)F=p′122(1m1+1m2) . If p′1=−p1 , then particle collides with each other and rebounds back and have same speed. The situation p′1=+p1 can only occur if particle does not collide, but they pass by each other.

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Answer 3

Question

Chapter 8, Problem 91P

To determine

The total kinetic energy before collision in terms of m1 ,m2 and p1 , the total kinetic energy after collision in terms of m1 ,m2 and p′1 and the situation for p′1=+p1 .

Expert Solution & Answer

Answer to Problem 91P

The total kinetic energy before collision in terms of m1 ,m2 and p1 is (K.E)I=p122(1m1+1m2) , The total kinetic energy after collision in terms of m1 ,m2 and p′1 is (K.E)F=p′122(1m1+1m2) . If p′1=−p1 , then particle collides with each other and rebounds back and have same speed. The situation p′1=+p1 can only occur if particle does not collide, but they pass by each other.

Explanation of Solution

Given:

The mass of particle 1 is m1 .

The mass of particle 2 is m2 .

Formula Used:

The expression for conservation of momentum is given by,

p′1+p′2=pcm

The expression for kinetic energy before collision is given by,

(K.E)I=12m1v12+12m2v22

The expression for kinetic energy after collision is given by,

(K.E)F=12m1v′12+12m2v′22

The expression for conservation of energy is,

(K.E)I=(K.E)F

Calculation:

The expression for conservation of momentum is calculated as,

p′1+p′2=pcmp′1+p′2=0p′2=−p′1

The expression for kinetic energy before collision is calculated as,

(K.E)I=12m1v12+12m2v22=12m1v12⋅m1m1+12m2v22⋅m2m2=m12v122m1+m12v222m2=p122m1+p222m2

Further simplify the above,

(K.E)I=p122m1+ ( − p 1 )22m2=p122m1+p122m2(K.E)I=p122(1 m 1 +1 m 2 )

The expression for kinetic energy after collision is calculated as,

(K.E)F=12m1v′12+12m2v′22=12m1v′12⋅m1m1+12m2v′22⋅m2m2=m12 v ′122m1+m12 v ′222m2= p ′122m1+ p ′222m2

Further simplify the above,

(K.E)F= p ′122m1+ ( − p ′ 1 )22m2= p ′122m1+ p ′122m2(K.E)F= p ′122(1 m 1 +1 m 2 )

The expression for conservation of energy is calculated as,

(K.E)F=(K.E)I p ′122(1 m 1 +1 m 2 )=p122(1 m 1 +1 m 2 )p′12=p12p′1=±p1

Conclusion:

Therefore, the total kinetic energy before collision in terms of m1 ,m2 and p1 is. (K.E)I=p122(1m1+1m2) , The total kinetic energy after collision in terms of m1 ,m2 and p′1 is (K.E)F=p′122(1m1+1m2) . If p′1=−p1 , then particle collides with each other and rebounds back and have same speed. The situation p′1=+p1 can only occur if particle does not collide, but they pass by each other.

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Answer 4

Question

Chapter 8, Problem 91P

To determine

The total kinetic energy before collision in terms of m1 ,m2 and p1 , the total kinetic energy after collision in terms of m1 ,m2 and p′1 and the situation for p′1=+p1 .

Expert Solution & Answer

Answer to Problem 91P

The total kinetic energy before collision in terms of m1 ,m2 and p1 is (K.E)I=p122(1m1+1m2) , The total kinetic energy after collision in terms of m1 ,m2 and p′1 is (K.E)F=p′122(1m1+1m2) . If p′1=−p1 , then particle collides with each other and rebounds back and have same speed. The situation p′1=+p1 can only occur if particle does not collide, but they pass by each other.

Explanation of Solution

Given:

The mass of particle 1 is m1 .

The mass of particle 2 is m2 .

Formula Used:

The expression for conservation of momentum is given by,

p′1+p′2=pcm

The expression for kinetic energy before collision is given by,

(K.E)I=12m1v12+12m2v22

The expression for kinetic energy after collision is given by,

(K.E)F=12m1v′12+12m2v′22

The expression for conservation of energy is,

(K.E)I=(K.E)F

Calculation:

The expression for conservation of momentum is calculated as,

p′1+p′2=pcmp′1+p′2=0p′2=−p′1

The expression for kinetic energy before collision is calculated as,

(K.E)I=12m1v12+12m2v22=12m1v12⋅m1m1+12m2v22⋅m2m2=m12v122m1+m12v222m2=p122m1+p222m2

Further simplify the above,

(K.E)I=p122m1+ ( − p 1 )22m2=p122m1+p122m2(K.E)I=p122(1 m 1 +1 m 2 )

The expression for kinetic energy after collision is calculated as,

(K.E)F=12m1v′12+12m2v′22=12m1v′12⋅m1m1+12m2v′22⋅m2m2=m12 v ′122m1+m12 v ′222m2= p ′122m1+ p ′222m2

Further simplify the above,

(K.E)F= p ′122m1+ ( − p ′ 1 )22m2= p ′122m1+ p ′122m2(K.E)F= p ′122(1 m 1 +1 m 2 )

The expression for conservation of energy is calculated as,

(K.E)F=(K.E)I p ′122(1 m 1 +1 m 2 )=p122(1 m 1 +1 m 2 )p′12=p12p′1=±p1

Conclusion:

Therefore, the total kinetic energy before collision in terms of m1 ,m2 and p1 is. (K.E)I=p122(1m1+1m2) , The total kinetic energy after collision in terms of m1 ,m2 and p′1 is (K.E)F=p′122(1m1+1m2) . If p′1=−p1 , then particle collides with each other and rebounds back and have same speed. The situation p′1=+p1 can only occur if particle does not collide, but they pass by each other.

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Answer 5

Chapter 8, Problem 91P

To determine

The total kinetic energy before collision in terms of m1 ,m2 and p1 , the total kinetic energy after collision in terms of m1 ,m2 and p′1 and the situation for p′1=+p1 .

Expert Solution & Answer

Answer to Problem 91P

The total kinetic energy before collision in terms of m1 ,m2 and p1 is (K.E)I=p122(1m1+1m2) , The total kinetic energy after collision in terms of m1 ,m2 and p′1 is (K.E)F=p′122(1m1+1m2) . If p′1=−p1 , then particle collides with each other and rebounds back and have same speed. The situation p′1=+p1 can only occur if particle does not collide, but they pass by each other.

Explanation of Solution

Given:

The mass of particle 1 is m1 .

The mass of particle 2 is m2 .

Formula Used:

The expression for conservation of momentum is given by,

p′1+p′2=pcm

The expression for kinetic energy before collision is given by,

(K.E)I=12m1v12+12m2v22

The expression for kinetic energy after collision is given by,

(K.E)F=12m1v′12+12m2v′22

The expression for conservation of energy is,

(K.E)I=(K.E)F

Calculation:

The expression for conservation of momentum is calculated as,

p′1+p′2=pcmp′1+p′2=0p′2=−p′1

The expression for kinetic energy before collision is calculated as,

(K.E)I=12m1v12+12m2v22=12m1v12⋅m1m1+12m2v22⋅m2m2=m12v122m1+m12v222m2=p122m1+p222m2

Further simplify the above,

(K.E)I=p122m1+ ( − p 1 )22m2=p122m1+p122m2(K.E)I=p122(1 m 1 +1 m 2 )

The expression for kinetic energy after collision is calculated as,

(K.E)F=12m1v′12+12m2v′22=12m1v′12⋅m1m1+12m2v′22⋅m2m2=m12 v ′122m1+m12 v ′222m2= p ′122m1+ p ′222m2

Further simplify the above,

(K.E)F= p ′122m1+ ( − p ′ 1 )22m2= p ′122m1+ p ′122m2(K.E)F= p ′122(1 m 1 +1 m 2 )

The expression for conservation of energy is calculated as,

(K.E)F=(K.E)I p ′122(1 m 1 +1 m 2 )=p122(1 m 1 +1 m 2 )p′12=p12p′1=±p1

Conclusion:

Therefore, the total kinetic energy before collision in terms of m1 ,m2 and p1 is. (K.E)I=p122(1m1+1m2) , The total kinetic energy after collision in terms of m1 ,m2 and p′1 is (K.E)F=p′122(1m1+1m2) . If p′1=−p1 , then particle collides with each other and rebounds back and have same speed. The situation p′1=+p1 can only occur if particle does not collide, but they pass by each other.

Answer 6

Chapter 8, Problem 91P

To determine

The total kinetic energy before collision in terms of m1 ,m2 and p1 , the total kinetic energy after collision in terms of m1 ,m2 and p′1 and the situation for p′1=+p1 .

Expert Solution & Answer

Answer to Problem 91P

The total kinetic energy before collision in terms of m1 ,m2 and p1 is (K.E)I=p122(1m1+1m2) , The total kinetic energy after collision in terms of m1 ,m2 and p′1 is (K.E)F=p′122(1m1+1m2) . If p′1=−p1 , then particle collides with each other and rebounds back and have same speed. The situation p′1=+p1 can only occur if particle does not collide, but they pass by each other.

Explanation of Solution

Given:

The mass of particle 1 is m1 .

The mass of particle 2 is m2 .

Formula Used:

The expression for conservation of momentum is given by,

p′1+p′2=pcm

The expression for kinetic energy before collision is given by,

(K.E)I=12m1v12+12m2v22

The expression for kinetic energy after collision is given by,

(K.E)F=12m1v′12+12m2v′22

The expression for conservation of energy is,

(K.E)I=(K.E)F

Calculation:

The expression for conservation of momentum is calculated as,

p′1+p′2=pcmp′1+p′2=0p′2=−p′1

The expression for kinetic energy before collision is calculated as,

(K.E)I=12m1v12+12m2v22=12m1v12⋅m1m1+12m2v22⋅m2m2=m12v122m1+m12v222m2=p122m1+p222m2

Further simplify the above,

(K.E)I=p122m1+ ( − p 1 )22m2=p122m1+p122m2(K.E)I=p122(1 m 1 +1 m 2 )

The expression for kinetic energy after collision is calculated as,

(K.E)F=12m1v′12+12m2v′22=12m1v′12⋅m1m1+12m2v′22⋅m2m2=m12 v ′122m1+m12 v ′222m2= p ′122m1+ p ′222m2

Further simplify the above,

(K.E)F= p ′122m1+ ( − p ′ 1 )22m2= p ′122m1+ p ′122m2(K.E)F= p ′122(1 m 1 +1 m 2 )

The expression for conservation of energy is calculated as,

(K.E)F=(K.E)I p ′122(1 m 1 +1 m 2 )=p122(1 m 1 +1 m 2 )p′12=p12p′1=±p1

Conclusion:

Therefore, the total kinetic energy before collision in terms of m1 ,m2 and p1 is. (K.E)I=p122(1m1+1m2) , The total kinetic energy after collision in terms of m1 ,m2 and p′1 is (K.E)F=p′122(1m1+1m2) . If p′1=−p1 , then particle collides with each other and rebounds back and have same speed. The situation p′1=+p1 can only occur if particle does not collide, but they pass by each other.

Answer 7

Chapter 8, Problem 91P

To determine

The total kinetic energy before collision in terms of m1 ,m2 and p1 , the total kinetic energy after collision in terms of m1 ,m2 and p′1 and the situation for p′1=+p1 .

Answer 8

Expert Solution & Answer

Answer to Problem 91P

The total kinetic energy before collision in terms of m1 ,m2 and p1 is (K.E)I=p122(1m1+1m2) , The total kinetic energy after collision in terms of m1 ,m2 and p′1 is (K.E)F=p′122(1m1+1m2) . If p′1=−p1 , then particle collides with each other and rebounds back and have same speed. The situation p′1=+p1 can only occur if particle does not collide, but they pass by each other.

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

Explanation of Solution

Given:

The mass of particle 1 is m1 .

The mass of particle 2 is m2 .

Formula Used:

The expression for conservation of momentum is given by,

p′1+p′2=pcm

The expression for kinetic energy before collision is given by,

(K.E)I=12m1v12+12m2v22

The expression for kinetic energy after collision is given by,

(K.E)F=12m1v′12+12m2v′22

The expression for conservation of energy is,

(K.E)I=(K.E)F

Calculation:

The expression for conservation of momentum is calculated as,

p′1+p′2=pcmp′1+p′2=0p′2=−p′1

The expression for kinetic energy before collision is calculated as,

(K.E)I=12m1v12+12m2v22=12m1v12⋅m1m1+12m2v22⋅m2m2=m12v122m1+m12v222m2=p122m1+p222m2

Further simplify the above,

(K.E)I=p122m1+ ( − p 1 )22m2=p122m1+p122m2(K.E)I=p122(1 m 1 +1 m 2 )

The expression for kinetic energy after collision is calculated as,

(K.E)F=12m1v′12+12m2v′22=12m1v′12⋅m1m1+12m2v′22⋅m2m2=m12 v ′122m1+m12 v ′222m2= p ′122m1+ p ′222m2

Further simplify the above,

(K.E)F= p ′122m1+ ( − p ′ 1 )22m2= p ′122m1+ p ′122m2(K.E)F= p ′122(1 m 1 +1 m 2 )

The expression for conservation of energy is calculated as,

(K.E)F=(K.E)I p ′122(1 m 1 +1 m 2 )=p122(1 m 1 +1 m 2 )p′12=p12p′1=±p1

Conclusion:

Therefore, the total kinetic energy before collision in terms of m1 ,m2 and p1 is. (K.E)I=p122(1m1+1m2) , The total kinetic energy after collision in terms of m1 ,m2 and p′1 is (K.E)F=p′122(1m1+1m2) . If p′1=−p1 , then particle collides with each other and rebounds back and have same speed. The situation p′1=+p1 can only occur if particle does not collide, but they pass by each other.

Answer 12

Ch. 8 - Prob. 1P Ch. 8 - Prob. 2P Ch. 8 - Prob. 3P Ch. 8 - Prob. 4P Ch. 8 - Prob. 5P Ch. 8 - Prob. 6P Ch. 8 - Prob. 7P Ch. 8 - Prob. 8P Ch. 8 - Prob. 9P Ch. 8 - Prob. 10P

The total kinetic energy before collision in terms of m 1 , m 2 and p 1 , the total kinetic energy after collision in terms of m 1 , m 2 and p ′ 1 and the situation for p ′ 1 = + p 1 .

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The total kinetic energy before collision in terms of m1 ,m2 and p1 , the total kinetic energy after collision in terms of m1 ,m2 and p′1 and the situation for p′1=+p1 .

Answer to Problem 91P

Explanation of Solution

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Chapter 8 Solutions