Least action and the maximum-coupling approximations in the theory of spontaneous fission

TL;DR

This paper explores a simplified theoretical approach to spontaneous fission dynamics using least-action and maximum-coupling approximations within a configuration-interaction framework, revealing exponential decay rate dependencies.

Contribution

It introduces maximum-coupling approximation methods that simplify CI calculations and effectively estimate decay rates in spontaneous fission models.

Findings

Decay rate decreases exponentially with the number of blocks.

Maximum-coupling approximation performs well in schematic models.

Adiabatic approximation underestimates the coupling.

Abstract

We investigate the dynamics of spontaneous fission in a configuration-interaction (CI) approach. In that formalism the decay rate is governed by an effective interaction coupling the ground-state configuration and a fission doorway configuration, with the interaction strength determined by inverting a high-dimensioned CI Hamiltonian matrix that may have a block-tridiagonal structure. It is shown that the decay rate decreases exponentially with the number of blocks at a rate determined by the largest eigenvalue of a matrix in the block space for Hamiltonians with identical off-diagonal blocks. The theory is greatly simplified by approximations similar in spirit to the adiabatic and the least-action approximations in continuum representations. Here each block is replaced by a single matrix element. While the adiabatic reduction underestimates the coupling, a reduction based on a maximum-coupling approximation works well in a schematic CI model.