Help with a collisions question

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In summary: And yes, the extra momenta in opposite directions will cancel each other out, resulting in a total momentum of zero.In summary, the problem involves two blocks colliding in a one-dimensional collision. The first block has a mass of 0.50 kg and is initially moving to the right at 2.4 m/s towards a second block of mass 0.80 kg that is initially at rest. When the blocks collide, a cocked spring releases 1.2 J of energy into the system. The questions ask for the velocities of each block after the collision. To solve this problem, one must use equations for conservation of momentum and kinetic energy. It is important to note that the total momentum and kinetic energy of the
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joker_900
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Two blocks can collide in a one-dimensional collision. The block on the left hass a mass of 0.50 kg and is initially moving to the right at 2.4 m/s toward a second block of mass 0.80 kg that is initially at rest. When the blocks collide, a cocked spring releases 1.2 J of energy into the system.
(a) What is the velocity of the first block after the collision?
(b) What is the velocity of the second block after the collision?

I don't know what to do. I assume equal momentum is given by the spring to each block, but i tried working out the momentum given to the system by pretending it was 1 big block and working out the KE and so the momentum. I though this was the momentum given to each block so worked out the velocity given to each block by the spring and adding it on to the two velocities i found using simultaneous equations of momentum and kinetic energy. It didn't work :(. I don't know what else to do without knowing how the energy is distributed between the two blocks.
 
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Hints:
(1) Is momentum conserved during the collision?
(2) How does the total kinetic energy after the collision compare to the total KE before the collision?

Translate your answers into equations and solve.
 
  • #3
The kinetic energy after must be 1.2J greater than the kinetic energy before right? With the momentum equation, momentum can't be conserved if you release more energy into the system, because each block will have a greater momentum than they would have were the spring not there. Will overall momentum of the system be the same with or without the spring - do the extra momentums in opposite directions caused by the spring cancel?
 
  • #4
joker_900 said:
The kinetic energy after must be 1.2J greater than the kinetic energy before right?
Right.
With the momentum equation, momentum can't be conserved if you release more energy into the system, because each block will have a greater momentum than they would have were the spring not there.
Conservation of momentum refers to the total momentum of the system, not the individual momenta of each block. And remember that momentum is a vector.
Will overall momentum of the system be the same with or without the spring - do the extra momentums in opposite directions caused by the spring cancel?
The total momentum of any system remains the same as long as no external forces act on it. (The spring is an internal force to the two-block system.)
 

1. What is a collision in physics?

A collision in physics is an event in which two or more objects come into contact with each other and exert forces on each other, resulting in a change in their motion or deformation of the objects.

2. What are the different types of collisions?

There are two main types of collisions: elastic and inelastic. In an elastic collision, both the kinetic energy and momentum of the objects are conserved. In an inelastic collision, the kinetic energy is not conserved and some energy is lost due to deformation or other forces.

3. How do you calculate the momentum of an object in a collision?

The momentum of an object can be calculated by multiplying its mass by its velocity. In a collision, the total momentum before the collision is equal to the total momentum after the collision.

4. What is the law of conservation of momentum?

The law of conservation of momentum states that in a closed system, the total momentum before and after a collision must be equal. This means that the sum of the momenta of all objects involved in the collision must be the same before and after the collision.

5. How do you determine the direction of the resulting velocities in a collision?

The direction of the resulting velocities in a collision can be determined by using the law of conservation of momentum. The direction of the resulting velocities will depend on the direction and magnitude of the initial velocities and the masses of the objects involved in the collision.

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