Block A (mass = m a ) is attached to the left end of an ideal (massless) spring

Question

Block A (mass = ma) is attached to the left end of an ideal (massless) spring with stiffness value of k.

Block B (mass = mb) is not attached to anything. Both masses are supported by a level surface.

That surface is frictionless in the region where block A can travel, but it offers friction (uk, us) in the region where block B can travel. There is no air drag.

Initially, block B is at rest, and block A is moving to the right at a known speed vA (with the spring relaxed). Then the spring's right end collides with block B.

Summary of known values: mA, k, mB, uk, us, vA, g.

Show (with full diagrams and/or equation, as necessary) how you could calculate whether block B slips before block A stops.

Explanation / Answer

if A stops then

using energy conservation

0.5 * k * X ^2 = 0.5 * mA * vA ^2

X = sqrt(mA * vA^2 /k)

now this compression in spring will apply force on B

kX = force spring exerts on B

us * mB * g =minimum force that is required to move B

if Kx > us * mB * g

then it means B slips before A comes to stop   

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