A uranium nucleus of mass 238, initially at rest, decays by emitting an alpha pa

Question

A uranium nucleus of mass 238, initially at rest, decays by emitting an alpha particle of mass 4, leaving behind a thorium nucleus of mass 234. If the alpha particle goes due north, in what direction will the thorium nucleus move and why? (The masses given are in atomic mass units where the mass on one proton or neutron is 1. The mass of a proton or neutron in SI units is 1.67x10-27 kg, the latter is irrelevant to the problem.)

How many times faster will the alpha particle be moving than the thorium nucleus (what is the ratio of their speeds)?

What fraction of the total kinetic energy does the recoiling thorium nucleus carry?

Explanation / Answer

Mu = mass of uranium = 238

Mth = mass of thorium = 234

Ma = mass of alpha particle = 4

V = initial velocity of Uranium particle before decay = 0

Vfa = velocity of alpha particle after decay

Vfth = velocity of thorium particle after decay

Using conservation of momentum

Mu V = Ma Vfa + Mth Vfth

238 x 0 = 4 Vfa + 234 Vfth

Vfth = - 0.018 Vfa

hence the thorium particle moves in opposite direction of alpha particle which is south.

Vfa = - 58.5 Vfth

alpha particle moves 58.5 times faster

Total Kinetic energy = (0.5) Ma Vfa2 + (0.5) Mth Vfth2

Total Kinetic energy = (0.5) (4 (58.5 Vfth)2) + 234 Vfth2 )

Kinetic energy of thorium nucleus = (0.5) 234 Vfth2

fraction = (0.5) 234Vfth2 / ((0.5) (4 (58.5 Vfth)2) + 234 Vfth2 ))

fraction = 234 / (4 (58.5)2 + 234)

fraction = 0.0168

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