The Rate of Decay of Fission Products

Abstract

By considering the fission products as a sort of statistical assembly, calculations have been made of the $\beta$-disintegrations per second and of the total energy emitted per second at any time after fission has taken place (cf. Fig. 6). The results are in good agreement with experiment. The theoretical work is based on the assumption that the mass of a nucleus of mass number $A$ and charge $Z$ is given by $a{\left(Z_0\mathrm{}\right(A)-Z)}^2+b$. Empirical values for $a$ and $b$ are used. Use is also made of an approximate empirical relationship between half-life and disintegration energy. A further basic hypothesis which is important for the results at very short times after fission has taken place is that, in the most probable way of splitting, the chain lengths of the light and heavy fragments are equal and that there is not much deviation from this most probable mode of fission. (See L. E. Glendenin, C. D. Coryell, R. R. Edwards, and M. H. Feldman, CL-LEG-1. A tentative explanation has been given recently by R. D. Present, Phys. Rev. 72, 7 (1947).) The average number of $\beta$-disintegrations per fission is found to be 6; the average energy of all radiations ($\beta$, $\gamma$, and neutrino) of the fission products is 21.5±3 Mev. Apparently, about half of this energy escapes in the form of neutrinos and a quarter is emitted in the form of $\beta$ and in the form of $\gamma$ rays.