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Chapter 10: Q5Q (page 410)

What happens to the velocities of the two objects when a high-mass object hits a low-mass object head-on? When a low-mass object hits a high-mass object head-on?

Short Answer

Expert verified

When a high-mass object hits a low-mass object head-on, the velocity of the low-mass object increases but the velocity of the high-mass object remains the same. On the other hand, when a low-mass object hits a high-mass object head-on, the low-mass object rebounds with the same speed but the velocity of the high-mass object remains the same.

Step by step solution

01

Significance of the law of conservation of momentum of a system

This law states that the momentum of a particular system before and after the collision is constant if no external force acts on the system.

The law of conservation of momentum gives the velocities of the light and the heavy objects after the collision.

02

Determination of the velocities of the light and the heavy object

From the law of conservation of momentum, when a high mass object hits a low mass object, the low mass object moves with a higher speed and also with higher acceleration. As the force exerted is directly proportional to the acceleration, so, when force is exerted then the velocity of the low-mass object also increases but the high-mass object remains the same as there is no effect of force on that due to the reason that the mass of the heavy object is large.

Apart from that, when a low-mass object hits a high-mass object, the low-mass object rebounds with the same speed but the velocity of the high-mass object does not change. This is also due to the difference in mass. So, the low-mass object will not affect the high-mass object.

Thus, when a high-mass object hits a low-mass object head-on, the velocity of the low-mass object increases but the velocity of the high-mass object remains the same. On the other hand, when a low-mass object hits a high-mass object head-on, the low-mass object rebounds with the same speed but the velocity of the high-mass object remains the same.

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Most popular questions from this chapter

A uranium atom traveling at speed4×104m/scollides elastically with a stationary hydrogen molecule, head-on. What is the approximate final speed of the hydrogen molecule?

A beam of high-energy π − (negative pions) is shot at a flask of liquid hydrogen, and sometimes a pion interacts through the strong interaction with a proton in the hydrogen, in the reaction ττ-+p+→ττ-+X+, where X + is a positively charged particle of unknown mass. The incoming pion momentum is 3 GeV/c (1GeV = 1000 MeV = 1 × 109 electron-volts). The pion is scattered through , and its momentum is measured to be 1510 MeV/c (this is done by observing the radius of curvature of its circular trajectory in a magnetic field). A pion has a rest energy of 140 MeV, and a proton has a rest energy of 938 MeV. What is the rest mass of the unknown X+ particle, in MeVc2? Explain your work carefully. It is advantageous to write the equations not in terms of v but rather in terms of E and p; remember that E2-(pc)2=(mc2)2.

Two asteroids in outer space collide and stick together. The mass of each asteroid, and the velocity of each asteroid before the impact, are known. To find the momentum of the stuck-together asteroids after the impact, what approach would be useful? (1) Use the Energy Principle. (2) Use the Momentum Principle. (3) It depends on whether or not the speed of the asteroids was near the speed of light. (4) Use the relationship among velocity, displacement, and time. (5) It depends on whether the collision was elastic or inelastic.

A hydrogen atom is at rest, in the first excited state, when it emits a photon of energy 10.2 eV. (a) What is the speed of the ground-state hydrogen atom when it recoils due to the photon emission? Remember that the magnitude of the momentum of a photon of energy E is p = E/c. Make the initial assumption that the kinetic energy of the recoiling atom is negligible compared to the photon energy. (b) Calculate the kinetic energy of the recoiling atom. Is this kinetic energy indeed negligible compared to the photon energy?

What is it about analyzing collisions in the center-of-mass frame that simplifies the calculations?
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