The binding energy per nucleon for `C^(12)` is `7.68 MeV` and that for `C^(13)` is `7.5 MeV` The energy required to remove a neutron from `C^(13)` is

The binding energy per nucleon for C^(12) is 7.68 MeV and that for C^(13) is 7.47 MeV. What is the energy required to remove a neutron from C^(13) ?

Binding energy per nucleon for C^(12) is 7.68 MeV and for C^(13) is 7.74 MeV . The energy required to remove a neutron from C^(13) is .

The binding energy per nucleon of ._(5)B^(10) is 8 MeV and that of ._(5)B^(11) is 7.5 MeV. The energy required to remove a neutron from ._(5)B^(11) is (mass of electron and proton are 9.11 xx 10^(-21) kg and 1.67 xx 10^(-27) kg respectively.

The binding energy per nucleon of O^16 is 7.97 MeV and that of O^17 is 7.75 MeV . The energy (in MeV) required to remove a neutron from O^17 is.

The binding energy per nucleon of O^16 is 7.97 MeV and that of O^17 is 7.75 MeV . The energy (in MeV) required to remove a neutron from O^17 is.

In a fission reaction ._92^236 U rarr ^117 X + ^117Y + n + n , the binding energy per nucleon of X and Y is 8.5 MeV whereas of .^236 U is 7.6 MeV . The total energy liberated will be about.

If the binding energy of the electron in a hydrogen atom is 13.6 eV , the energy required to remove the electron from the first excited state of Li^(++) is

The binding energy per nucleon is maximum at A=56 and its value is around ____ Mev/ Nucleon

The binding energies per nucleon for deuteron ( _1H^2 ) and helium ( _2He^4) are 1.1 MeV and 7.0 MeV respectively. The energy released when two deuterons fuse to form a helium nucleus ( _2He^4 ) is

The binding energy per nucleon of deuterium and helium nuclei are 1.1 MeV and 7.0 MeV respectively. When two deuterium nuclei fuse to form a helium nucleus the energy released in the fusion is