Let `m_p` be the mass of a proton , `m_n` the mass of a neutron, `M_1` the mass of a `._10^20Ne` nucleus and `M_2` the mass of a `._20^40Ca` nucleus . Then

Let m_(p) be the mass of a poton , M_(1) the mass of a _(10)^(20) Ne nucleus and M_(2) the mass of a _(20)^(40) Ca nucleus . Then

Mp depends the mass of a proton and Mn that of a neutron. A given nucleus, of binding energy B, contains Z protons and N neutrons. The mass M(N,Z) of the nucleus is given by (c is the velocity of light)

M_p denotes the mass of a proton and M_n that of a neutron. A given nucleus, of binding energy B , contains Z protons and N neutrons. The mass M(N,Z) of the nucleus is given by.

The mass of a proton is 1836 times more than the mass of an electron. It a sub-atomic of mass (m) 207 times the mass of electron is captured by the nucleus, then the first ionization potential of H :

If m_(p) and m_(n) are masses of proton and neutron respectively and M_(1) and M_(2) are masses of ._(10)MeNe^(20) and ._(20)Ca^(40) nucleus repectively, then:

If in a nuclear fusion process the masses of the fusing nuclei be m_(1) and m_(2) and the mass of the resuktant nucleus be m_(3) , then