Extended time-dependent generator coordinate method study of induced fission (II): total kinetic energy distribution

TL;DR

This paper develops a model using the time-dependent generator coordinate method with dissipation to calculate the total kinetic energy distribution of fission fragments, applied to $^{228}$Th at various temperatures.

Contribution

It extends the TDGCM framework to include dissipation effects and computes TKE distributions considering temperature, providing a more comprehensive fission dynamics model.

Findings

Successfully calculated TKE distribution for $^{228}$Th induced fission.

Incorporated dissipation effects into the TDGCM framework.

Demonstrated the model's application in a 3D collective coordinate space.

Abstract

A model is developed to calculate the total kinetic energy (TKE) distribution of fission fragments in the framework of the time-dependent generator coordinate method (TDGCM), extended to include dissipation effects in the description of induced fission dynamics. Starting from an expression for the dissipative term in the GCM Hamiltonian that determines the time evolution of a statistical collective wave function, derived in the first part of this work, the integrated flux of the probability current through the scission hyper-surface can be computed at different temperatures. The kinetic energy at scission for a specific pair of fragments at a given temperature is determined by the energy balance formula. By folding the kinetic energies of the fragments with the flux of the probability current, the TKE distribution is calculated. The method is illustrated with a calculation of the TKE distribution for induced fission of $^{228}$Th, in the 3D space of collective coordinates: axially-symmetric quadrupole and octupole deformations, and nuclear temperature.