A particle of mass $m$ $m$ moving with speed $v$ $v$ hits elastically another stationary particle of mass $2 m$ $2m$ inside a smooth horizontal circular tube of radius $r$ $r$ . The time after which the second collision will happen?

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A particle of mass $m$ $m$ moving with speed $v$ $v$ hits elastically another stationary particle of mass $2 m$ $2m$ inside a smooth horizontal circular tube of radius $r$ $r$ . The time after which the second collision will happen?

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Answer 1 · 2018-03-05T20:19:35

The circumference of the circle is $2 π r$ $2pir$ units, so that is the net distance the particles will travel after the collision. The time taken will be given by $t = \frac{2 π r}{v}$ $t=(2pir)/v$

Explanation:

The momentum before the collision will be $m v$ $mv$ . Momentum is conserved, so the momentum after the collision will be the same. It will be distributed between the two objects.

Call the velocity of the particle of mass $m$ $m$ after the collision $v_{1}$ $v_1$ and the velocity of the particle of mass $2 m$ $2m$ $v_{2}$ $v_2$ .

$m v = m v_{1} + 2 m v_{2}$ $mv=mv_1+2mv_2$

We can cancel out $m$ $m$ and have:

$v = v_{1} + 2 v_{2}$ $v=v_1+2v_2$

Since the collision is elastic, kinetic energy is conserved in the collision

$\frac{1}{2} m v^{2} = \frac{1}{2} m v_{1}^{2} + \frac{1}{2} 2 m v_{2}^{2}$ $1/2mv^2 = 1/2mv_1^2+1/2 2mv_2^2$

Canceling out $\frac{1}{2} m$ $1/2m$ gives us

$v^{2} = v_{1}^{2} + 2 v_{1}^{2}$ $v^2 = v_1^2+2v_1^2$

The two equations can be rewritten in the form

$color(red)(v-v_1 = 2v_2),qquad v^2-v_1^2 = 2v_2^2$

Dividing both sides of the second equation by $v-v_1$
gives

$color(red)(v+v_1 =) {2v_2^2}/(2v_2)=color(red)(v_2)$

(Note that the last equation could have been directly obtained by using the alternative definition of elastic collisions - relative speed of approach equals that of separation - that would considerably shorten the answer!)

This implies that the relative speed of separation of the two objects is

$v_2-v_1 =v$

When the two bodies collide again, the distances traveled by them must differ by $2pi r$ .

The time taken for this must be

$t = {2pi r}/{v_2-v_1} = {2pi r}/v$

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A particle of mass $m$ $m$ moving with speed $v$ $v$ hits elastically another stationary particle of mass $2 m$ $2m$ inside a smooth horizontal circular tube of radius $r$ $r$ . The time after which the second collision will happen?

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Explanation:

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A particle of mass mmm moving with speed vvv hits elastically another stationary particle of mass 2m2m2m inside a smooth horizontal circular tube of radius rrr. The time after which the second collision will happen?

1 Answer

Explanation:

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A particle of mass $m$ $m$ moving with speed $v$ $v$ hits elastically another stationary particle of mass $2 m$ $2m$ inside a smooth horizontal circular tube of radius $r$ $r$ . The time after which the second collision will happen?