and explain in detail please. Thankyou!
in a perfectly elastic collision , there is no loss of kinetic energy so it is conserved
and momentum is conserved in all types of collisions so
option D) both the momentum and the Kinetic energy of the system are conserved is the correct answer
and explain in detail please. Thankyou! 1. In a perfectly ELASTIC collision between two perfectly rigid...
4 pts Question 1 Which of these statements is TRUE for perfectly elastic collision? OOnly momentum is conserved OBoth momentum and Kinetic energy are conserved OOnly kinetic energy is conserved None of the above Question 2 4 pts Which of these statement is TRUE for a perfectly inelastic collision? Only momentum is conserved None of the above Only Kinetic energy is conserved Both momentum and Kinetic energy are conserved
16. In a perfectly elastic collision Kinetic Energy is conserved for the system. (Remember that elastic collisions are ones where the objects bounce off of each other and don't stick.) On an air hockey table two identical pucks collide. Initially one is at rest and the other is moving with a speed of v. (Hint: How can the concept of momentum help with this problem?) a. What is the speed of each puck after the collision in terms of the...
Two objects undergo an elastic collision. Object 1 has a mass of 2.75 kg and object 2 a mass of 2.6 kg. Just prior to the collision, object 1 has a kinetic energy of 51 J and object 2 is at rest. What is the initial velocity of Object 1? What is the total kinetic energy of the two cart system after the collision? What is the total momentum of the two cart system after the collision?
In a glancing collision between two identical steel spheres, which of the following statements are correct? (Assume this collision is perfectly elastic. Select all that apply.) A) Kinetic energy in this collision will be conserved. B) Linear momentum will be conserved in this collision. C) The sum of the velocity vectors of the two spheres in the original direction of the incoming sphere after the collision will be equal to that of the incoming sphere. D) The velocities of the...
5. [1pt] Consider a perfectly elastic collision between two objects of equal mass. Object 1 is initially moving with a velocity v = 3.07 m/s while object 2 is at rest. What are the final velocities after the collision? Enter the final velocity of object 1 first. Correct, computer gets: 0.002+00 m/s, 3.07e+00 m/s 6. [1pt] If the objects have masses m = 2.37 kg and m2 = 4.94 kg, what are the final velocities of the objects after the...
Kinetic energy is only conserved in an inelastic collision. True False Two objects collide ans stick together. This is an elastic collision. True False Momentum is conserved in both elastic and inelastic collisions. True False
1 .How is momentum of a body affected by its speed? by its mass? 2. Momentum can be expressed in a. N/s b. N.s c. N.m d. N.m/s 3.When the velocity of a moving object is doubled, a. its acceleration is doubled c. its kinetic energy is doubled b. its momentum is doubled d. its potential energy is doubled 4.A body at rest has a. constant speed b. zero momentum c. zero kinetic energy d. variable speed...
2. In an elastic collision, energy is not conserved. Where does it go? A) It is transformed into heat and also used to deform colliding objects. B) It is converted into potential energy. C) It is transformed into momentum such that momentum is conserved. D) All of the above. E) None of the above.
A one-dimensional perfectly elastic collision occurs between two masses on a frictionless surface. The initial kinetic energies of the masses were 10 J and 5 J. After the collision the kinetic energy of one of the masses is 20 J. What is the kinetic energy of the other mass?
A 2.0-g particle moving at 7.0 m/s makes a perfectly elastic head-on collision with a resting 1.0-g object. (a) Find the speed of each particle after the collision. A 2.0-g particle moving at 7.0 m/s makes a perfectly elastic head-on collision with a resting 1.0-g object. (a) Find the speed of each particle after the collision. 2.0 g particle 2.33 m/s 1.0 g particle 9.33 m/s (b) Find the speed of each particle after the collision if the stationary particle...