A nuclear reaction is given as
`A + B rarr C+ D`
Binding energies of `A,B,C,` and `D`, are given as `B_1,B_2,B_3` and `B_4`. Find the energy released in the reaction.

In the reaction sequences A,B,C and D are given by the set:

Consider the nuclear reaction X^200 to A^110 + B^80 . The binding energy per nucleon for X, A and B are 7.4 MeV, 8.2 MeV and 8.1 MeV respectively. What is the energy released in the nuclear reaction ?

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

For the reaction : A + 2B rarr C + D , the expression of rate of reaction will be :

Consider the nuclear reaction , ""_1H^2 + ""_1H^3 to ""_2He^4 + ""_0n^1 . If the binding energies of ""_1H^1, ""_1H^3 " and " ""_2He^4 are a, b and c respectively (in MeV), then the energy released in this reaction is

For an elementary reaction, 2A + B rarr C + D the molecularity is

In the reaction A + B rarr C+D , the concentration of A and B are equal and the rate of the reaction is rate = k[A][B] . The integrated rate equation for this reaction is

In Figure, it is given that A B=B C and A D=E C . Prove that A B E~=C B D