COMPUTATION OF TWO-COMPONENT TRANSITION RATES OFPREEQUILIBRIUM STATES

Abstract

Different transition rates of the nuclear preequilibrium states in the exciton model
were numerically calculated in the present work, as well as the state density and matrix
element of the nuclear interaction. The calculations were based on the two-component
version of the exciton model. Some comparisons were made with earlier calculations,
and the results showed a good agreement. The results were explained on the bases of the
effects of the differences in the particle and hole numbers, as well as the type of the
incident particle and its energy. The conclusions indicated that preequilibrium nuclear
reactions induced by protons differ only by small fraction from those induced by
neurons at low exciton states. At higher exciton states with n>3, the transitions of the
types
−n
l and
+p
l differed significantly between neutron and proton transitions, which
may indicate distinguishable nuclear reaction mechanisms.