Consider the follwing nuclear reactions:
`._(92)^(238) M rarr ._(y)^(x)N + 2 ._(2)He^(4)`
`._(y)^(x)N rarr ._(B)^(A)L + 2beta^(+)`

Consider the following nuclear reactions : ._(92)^(238)M to _(Y)^(X)N+2_(2)^(4)"He " ,_(Y)^(X)N to _(B)^(A)L+2beta^(+) The number of neutrons in the element L is :

Consider the following nuclear reactions: ""_(92)""^(238)Mto.""_(y)""^(x)N+2.""_(2)""^(4)He, ""_(x)""^(y)Nto ""_(B)""^(A)L+2beta""^(+) The number of neutrons in the element L is

Unstable nuclei attain stability through disintegration. The nuclear stability is related to neutron proton ratio (n//p) . For stable nuclei n//p ratio lies close to unity for elements with low atmoic numbers (20 or less) but it is more than 1 for nuclei having higher atomic numbers. Nuclei having n//p ratio either very high or low undergo nuclear transformation. When n//p ratio is higher than required for stability, the nuclei have the tendency to emit beta -rays. while when n//p ratio is lower than required for stability, the nuclei either emits alpha -particles or a positron or capture K -electron. For reaction ._(92)M^(238) rarr ._(y)N^(x) + 2 ._(2)He^(4), ._(y)N^(x) rarr ._(B)L^(A) + 2 ._(-1)e^(0) The number of neutrons in the element L is

Balance the following nuclear reactions: a. ._(3)Li^(7) + ._(0)n^(1) rarr 2 ._(2)He^(4) + ? b. ._(42)Mo^(94) + ._(1)H^(2) rarr ._(0)n^(1) + ?

Consider the following nuclear reactions : I ._(7)^(14)N+._(2)^(4)Herarr._(8)^(17)O+X II ._(4)^(9)Be+._(2)^(4)Hrarr._(6)^(12)He+Y Then