363658 In the reaction \(_1^2H + _1^3H \to _2^4He + _0^1n,\) if the binding energies of \(_1^2H\,,\,_1^3H\) and \(_2^4He\) are respectively \(a,b\) and \(c\) (in \(MeV\)) then the energy (in \(MeV\)) released is

363659 The binding energies per nucleon of \({\text{L}}{{\text{i}}^7}\) and \({\text{H}}{{\text{e}}^4}\) are \(5.6\,\,{\text{MeV}}\) and \(7.06\,\,{\text{MeV}}\) respectively, then the energy of the reaction \({\text{L}}{{\text{i}}^7} + p \to 2\left[ {{}_2{\text{H}}{{\text{e}}^4}} \right]\) will be

363660 The binding energy per nucleon is maximum in the case of

363661 Mass numbers of the elements \(A,B,C\) and \(D\) are 30, 60, 90 and 120 respectively. The specific binding energy of them are \(5\,MeV,8.5\,MeV,8\,MeV\) and \(7\,MeV\) respectively. Then, in which of the following reactions energy is released? \((i){\rm{ }}D \to 2B\,\,\,\,\,\,\,(ii){\rm{ }}C \to B + A\)
(iii) \(B \to 2A\)

363658 In the reaction \(_1^2H + _1^3H \to _2^4He + _0^1n,\) if the binding energies of \(_1^2H\,,\,_1^3H\) and \(_2^4He\) are respectively \(a,b\) and \(c\) (in \(MeV\)) then the energy (in \(MeV\)) released is

363659 The binding energies per nucleon of \({\text{L}}{{\text{i}}^7}\) and \({\text{H}}{{\text{e}}^4}\) are \(5.6\,\,{\text{MeV}}\) and \(7.06\,\,{\text{MeV}}\) respectively, then the energy of the reaction \({\text{L}}{{\text{i}}^7} + p \to 2\left[ {{}_2{\text{H}}{{\text{e}}^4}} \right]\) will be

363660 The binding energy per nucleon is maximum in the case of

363661 Mass numbers of the elements \(A,B,C\) and \(D\) are 30, 60, 90 and 120 respectively. The specific binding energy of them are \(5\,MeV,8.5\,MeV,8\,MeV\) and \(7\,MeV\) respectively. Then, in which of the following reactions energy is released? \((i){\rm{ }}D \to 2B\,\,\,\,\,\,\,(ii){\rm{ }}C \to B + A\)
(iii) \(B \to 2A\)

363658 In the reaction \(_1^2H + _1^3H \to _2^4He + _0^1n,\) if the binding energies of \(_1^2H\,,\,_1^3H\) and \(_2^4He\) are respectively \(a,b\) and \(c\) (in \(MeV\)) then the energy (in \(MeV\)) released is

363659 The binding energies per nucleon of \({\text{L}}{{\text{i}}^7}\) and \({\text{H}}{{\text{e}}^4}\) are \(5.6\,\,{\text{MeV}}\) and \(7.06\,\,{\text{MeV}}\) respectively, then the energy of the reaction \({\text{L}}{{\text{i}}^7} + p \to 2\left[ {{}_2{\text{H}}{{\text{e}}^4}} \right]\) will be

363660 The binding energy per nucleon is maximum in the case of

363661 Mass numbers of the elements \(A,B,C\) and \(D\) are 30, 60, 90 and 120 respectively. The specific binding energy of them are \(5\,MeV,8.5\,MeV,8\,MeV\) and \(7\,MeV\) respectively. Then, in which of the following reactions energy is released? \((i){\rm{ }}D \to 2B\,\,\,\,\,\,\,(ii){\rm{ }}C \to B + A\)
(iii) \(B \to 2A\)

363658 In the reaction \(_1^2H + _1^3H \to _2^4He + _0^1n,\) if the binding energies of \(_1^2H\,,\,_1^3H\) and \(_2^4He\) are respectively \(a,b\) and \(c\) (in \(MeV\)) then the energy (in \(MeV\)) released is

363659 The binding energies per nucleon of \({\text{L}}{{\text{i}}^7}\) and \({\text{H}}{{\text{e}}^4}\) are \(5.6\,\,{\text{MeV}}\) and \(7.06\,\,{\text{MeV}}\) respectively, then the energy of the reaction \({\text{L}}{{\text{i}}^7} + p \to 2\left[ {{}_2{\text{H}}{{\text{e}}^4}} \right]\) will be

363660 The binding energy per nucleon is maximum in the case of

363661 Mass numbers of the elements \(A,B,C\) and \(D\) are 30, 60, 90 and 120 respectively. The specific binding energy of them are \(5\,MeV,8.5\,MeV,8\,MeV\) and \(7\,MeV\) respectively. Then, in which of the following reactions energy is released? \((i){\rm{ }}D \to 2B\,\,\,\,\,\,\,(ii){\rm{ }}C \to B + A\)
(iii) \(B \to 2A\)