An alpha-particle with kinetic energy `T_(alpha)= 7.0MeV` is scattered elastically by an initially stationary `Li^(6)` nucleus. Find the kinetic energy of the recoil nucleus if the angle of divergence of the two particle is `Theta= 60^(@)`.

An alpha-particle with kinetic energy `T_(alpha)= 7.0MeV` is scattered

1.	An alpha-particle with kinetic energy `T_(alpha)= 7.0MeV` is scattered elastically by an initially stationary `Li^(6)` nucleus. Find the kinetic energy of the recoil nucleus if the angle of divergence of the two particle is `Theta= 60^(@)`.
Answer» Initial momentum of the `alpha` particle is `sqrt(2mT_(alpha)) hat(i)` (where `hat(i)` is a unit vector in the incident direction.) Final momenta are respectively `vec(p)_(alpha)` and `vec(p_(Li)`. Conservation of momentum reads `vec(P)_(a)+vecP_(Li)= sqrt(2mT_(alpha))hat(i)` Squarting `p_(alpha)^(2)+p_(Li)+2p_(alpha)p_(Li)cos Theta= 2mT_(alpha)` (1) where `Theta` is the angle between `vec(p)_(alpha)` and `vec(p)_(Li)`. Also by energy conservation `(p_(alpha)^(2))/(2m)+(p_(L)^(2))/(2M)=T_(alpha)` (`m & M` are respectively the masses of `alpha` particle and `Li^(6)`.)So `p_(alpha)^(2)+(m)/(M)p_(Li)^(2)= 2mT_(alpha)` (2) Substituting (2) from (1) we see that `P_(Li)[(1-(m)/(M))p_(Li)+2p_(alpha)cos Theta]=0` Thus if `p_(Li) ~~ 0` `p_(alpha)= -(1)/(2)(1-(m)/(M))p_(Li)sec Theta`. Since `p_(alpha), p_(Li)` are both positive number (being magnitudes of vectors) we must have `-le cos Theta lt 0 if m lt M` This being understood, we write `(P_(Li)^(2))/(2M)[1+(M)/(4m)(1-(m)/(M))^(2) sec^(2)Theta]=T_(alpha)` Hence the recoil energy of the `L_(i)` nucleus is `(P_(Li)^(2))/(2M)=(T_(alpha))/(1+((M-m)^(2))/(4mM)sec^(2)Theta)` As we pointed out above `Theta ~~ 60^(@)`. If we take `Theta= 120^(@)`, we get recoil energy of `Li= 6MeV`.

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An alpha-particle with kinetic energy `T_(alpha)= 7.0MeV` is scattered elastically by an initially stationary `Li^(6)` nucleus. Find the kinetic energy of the recoil nucleus if the angle of divergence of the two particle is `Theta= 60^(@)`.

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