`M, M_(n) & M_(p)` denotes the masses of a nucleous of `._(Z)X^(A)` a neutron, and a proton respectively. If the nucleus is separated in to its individual protons and neutrons then

If m,m_n and m_p are masses of ._Z X^A nucleus, neutron and proton respectively.

Masses of nucleus, neutron an protons are M, mn and m_(p) respectively. If nucleus has been divided in to neutrons and protons, then

If M, m_n and m_p are masses (in kg) of nucleus X_z^A , neutron and proton respectively, then mass defect (Deltam) is equal to

m_(p) and m_(n) are masses of proton and neutron respectively. An element of mass M has Z protons and N neutrons then

m_(P) and m_(n) are masses of proton and neutron respectively. An element of mass m has Z protons and N neutrons, then

If M(A,Z), M_(p)and M_(n) denote the masses of the nucleus ._(Z)X^(A) , proton and neutron respectively in units of U (where 1U=931MeV//c^(2) ) and B.E. represents its B.E. in MeV, then

A nucleus ._(Z)X^(A) emits 2 alpha - particles and 3 beta - particles. The ratio of total protons and neutrons in the final nucleus is :

If M_(O) is the mass of an oxygen isotope ._(8)O^(17),M_(p) and M_(n) are the masses of a proton and a neutron, respectively, the nuclear binding energy of the isotope is