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Chapter 10: Q4 (page 410)

You know that a collision must be “elastic” if: (1) The colliding objects stick together. (2) The colliding objects are stretchy or squishy. (3) The sum of the final kinetic energies equals the sum of the initial kinetic energies. (4) There is no change in the internal energies of the objects (thermal energy, vibrational energy, etc.). (5) The momentum of the two-object system doesn’t change.

Short Answer

Expert verified

3) The sum of the final kinetic energies equals the sum of the initial kinetic energies and 4) there is no change in the internal energies of the objects (thermal energy, vibrational energy, etc.) and 5) the momentum of the two-object system doesn’t change.

Step by step solution

01

Significance of the law of conservation of momentum and elastic collision of a system

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

The total momentum of a system is conserved in an elastic collision and the mechanical energy is also conserved.

02

Determination of the elasticity of a collision

From the law of conservation of momentum, the momentum of a system gets conserved. Hence, all the bodies should be included while defining a system of bodies. However, when the objects collide and also bounce back between them, a moment redistribution amongst the bodies occurs. Moreover, in the elastic collision, the initial and the final kinetic energy of an object does not change.

Thus, 3) the sum of the final kinetic energies equals the sum of the initial kinetic energies and 4) there is no change in the internal energies of the objects (thermal energy, vibrational energy, etc.) and 5) the momentum of the two-object system doesn’t change.

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Most popular questions from this chapter

A ball whose mass is 0.2kg hits the floor with a speed of 8 m/s and rebounds upward with a speed of 7m/s. The ball was in contact with the floor for0.5ms0.5×10-3s.

(a) What was the average magnitude of the force exerted on the ball by the floor? (b) Calculate the magnitude of the gravitational force that the Earth exerts on the ball.

(c) In a collision, for a brief time there are forces between the colliding objects that are much greater than external forces. Compare the magnitudes of the forces found in parts (a) and (b).

Object A has mass mA=7kgand initial momentumPAj=(17,-5,0)kg.m/s2, just before it strikes object B , which has mass mA=11kg. Object B has initial momentum pBj=(4,6,0)kh.m/s2. After the collision, object A is observed to have final momentum PAf=(13,3,0)kg.m/s2. In the following questions, “initial” refers to values before the collisions, and “final” refers to values after the collision. Consider a system consisting of both objects and . Calculate the following quantities: (a) The total initial momentum of this system. (b) The final momentum of object B. (c) The initial kinetic energy of object A. (d) The initial kinetic energy of object B. (e) The final kinetic energy of object A. (f) The final kinetic energy of object B. (g) The total initial kinetic energy of the system. (h) The total final kinetic energy of the system. (i) The increase of internal energy of the two objects. (j) What assumption did you make about Q (energy flow from surroundings into the system due to a temperature difference)?

There is an unstable particle called the “sigma-minus” (), which can decay into a neutron and a negative pion (ττ):-n+ττ-. The mass of the -is 1196MeV/c2, the mass of the neutron is 939 MeV/c2, and the mass of the ττis 140MeV/c2. Write equations that could be used to calculate the momentum and energy of the neutron and the pion. You do not need to solve the equations, which would involve some messy algebra. However, be clear in showing that you have enough equations that you could in principle solve for the unknown quantities in your equations. It is advantageous to write the equations not in terms of v but rather in terms of E and p; remember that E2-(ρc)2=(mc2)2.

Redo Problem P21, this time using the concept of the center-of-momentum reference frame.

A car of mass 2300 kg collides with a truck of mass 4300 kg, and just after the collision the car and truck slide along, stuck together, with no rotation. The car’s velocity just before the collision was⟨38, 0, 0⟩m/s, and the truck’s velocity just before the collision was⟨−16, 0, 27⟩m/s. (a) Your first task is to determine the velocity of the stuck-together car and truck just after the collision. What system and principle should you use? (1) Energy Principle (2) Car plus truck (3) Momentum Principle (4) Car alone (5) Truck alone (b) What is the velocity of the stuck-together car and truck just after the collision? (c) In your analysis in part (b), why can you neglect the effect of the force of the road on the car and truck? (d) What is the increase in internal energy of the car and truck (thermal energy and deformation)? (e) Is this collision elastic or inelastic?

In outer space a rock whose mass is 3kg and whose velocity was(3900,-2900,3000)m/sstruck a rock with mass 13kg and velocity(220,-260,300)m/s. After the collision, the 3kg rock’s velocity is(3500,-2300,3500)m/s. (a) What is the final velocity of the 13kg rock? (b) What is the change in the internal energy of the rocks? (c) Which of the following statements about Q (transfer of energy into the system because of a temperature difference between system and surroundings) are correct? (1)Q0 because the duration of the collision was very short. (2)Q=Ethermal of the rocks. (3)Q0 because there are no significant objects in the surroundings. (4)Q=k of the rocks.
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