Consider the nuclear fission
`Ne^(20) rarr 2He and C^(12)` are, respectively 8.30 MeV, 7.07 MeV and 7.86 MeV, identify the correct statement

Consider the nuclear fission Ne^(20) rarr 2He + C^(12) .The binding energy per nucleon are 8.03 MeV, 7.07 MeV and 7.86 MeV respectively. identify the correct statement

If the binding energy per nucleon in ._(3)Li^(7) and ._(2)He^(4) nuclei are respectively 5.60 MeV and 7.06 MeV, then the energy of proton in the reaction ._(3)Li^(7) +p rarr 2 ._(2)He^(4) is

If the binding energy per nucleon in ._(3)Li^(7) and ._(2)He^(4) nuclei are respectively 5.60 MeV and 7.06 MeV, then the ebergy of proton in the reaction ._(3)Li^(7) +p rarr 2 ._(2)He^(4) is

If the binding energy per nucleon in ._(3)Li^(7) and ._(2)He^(4) nuclei are respectively 5.60 MeV and 7.06 MeV, then the ebergy of proton in the reaction ._(3)Li^(7) +p rarr 2 ._(2)He^(4) is

A nuclear fission is represented by the following reaction: U^(236) = X^(111) +Y^(122) +3n If the binding energies per nucleon of X^(111), Y^(122) and U^(236) are 8.6MeV, 8.5 MeV and 7.6 MeV respectively, then the energy released in the reaction will be-

If the binding energy per nucleon in L i^7 and He^4 nuclei are respectively 5.60 MeV and 7.06 MeV . Then energy of reaction L i^7 + p rarr 2_2 He^4 is.

Find the enrgy required of seperation of a Ne^(20) nucleus into two alpha-particles and a C^(12) nucleus if it is known that binding energies per one nucleon in Ne^(20), He^(4) and C^(12) nuclei are equal to 8.03, 7.07 , and 7.68MeV respectively.

Find the energy required for separation of a_(10)Ne^(20) nucleus into two alpha -particles and a_(6)C^(12) nucleus if it is known that the binding energies per nucleon in ._(10)Ne^(20), ._(2)He^(4) and ._(6)C^(12) nuclei are equal to 8.03, 7.07 and 7.68 MeV respectively.

Find the energy required for separation of a_(10)Ne^(20) nucleus into two alpha -particles and a_(6)C^(12) nucleus if it is known that the binding energies per nucleon in ._(10)Ne^(20), ._(2)He^(4) and ._(6)C^(12) nuclei are equal to 8.03, 7.07 and 7.68 MeV respectively.