Conservation of Energy Challenge Problem

AI Thread Summary
The discussion revolves around a physics problem involving a 2.0 kg cart with a spring colliding with a stationary 1.0 kg cart. The first part of the problem was solved using conservation of momentum and energy, resulting in a maximum spring compression of 0.046 m and a post-collision speed of 2.67 m/s for the combined carts. For the second part, participants suggest using the principles of elastic collisions and conservation of kinetic energy to find the final speeds of each cart. The discussion emphasizes that the collision is elastic, allowing for the use of relative velocities in the calculations. Overall, the problem illustrates key concepts in mechanics, including momentum conservation and energy transfer during collisions.
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Homework Statement


A 2.0 kg cart has a sping with k= 5000 N/m attached to its front, parallel to the ground. This cart rolls at 4.0 m/s toward a stationary 1.0 kg cart.

a) What is the maximum compression of the spring during the collision?

b) What is the speed of each cart after the collision?


Homework Equations



KE=(1/2)mv^2 Us=(1/2)kx^2

The Attempt at a Solution



I got the first part:

Using first conservation of momentum and assuming the cars stick together momentarily
then using conservation of energy

(2kg)(4m/s)=(3kg)v1
v1= 2.67 m/s
(.5)(2kg)(4m/s)^2=(.5)(5000N/m)(x)^2 + (.5)(3kg)(2.67m/s)^2
x= .046 m

But I'm not sure what to do with the second part. Any suggestions?
 
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But I'm not sure what to do with the second part. Any suggestions?

That's the easiest part. Since this was a completely elastic collision, the elastic co-eff =1. So, final relative velocity = initial relative velocity. This, combined with the conservation of momentum, gives you two unknowns with two eqns.

Of course, you can also use conservation of total KE, but that's lengthier.

Good job in solving part A.
 

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