Nuclear descent from the fission barrier in the presence of long--range memory effects

TL;DR

This study explores how long-range memory effects influence nuclear descent from a fission barrier, revealing significant slowing down, oscillatory behavior, and long descent times in uranium-236.

Contribution

It introduces a generalized Langevin model with power-law memory to analyze nuclear descent, providing analytical solutions and new insights into long-range memory effects.

Findings

Long-range memory causes stronger slowing down of nuclear descent.

Analytical trajectory found at a specific memory exponent.

Observed long descent times for uranium-236.

Abstract

We have investigated the peculiarities of nuclear descent from a parabolic fission barrier within a generalized Langevin equation with power--law $f(t-t')=(|t-t'|/\tau)^{-\alpha}$ memory function. We have observed much stronger slowing down of the nuclear descent in the presence of long--range memory effects, caused by the power--law memory function at $0<\alpha<1$, than in the presence of short--range memory effects, generated by exponential $f(t-t')={\rm exp}(-|t-t'|/\tau)$ memory function. At a specific value of the exponent $\alpha=1/2$ of the power--law memory function, it turned out possible to find analytically the trajectory of the descent and demonstrate that the long--range memory effects give rise to complex time oscillations of nuclear shape, becoming more frequent and damped with the correlation time $\tau$. We have found fairly long ($>10^{-20}~{\rm s}$) times of the descent of $^{\rm 236}{\rm U}$ at the values of the correlation time $\tau \sim [10^{-24}\div 10^{-23}]~{\rm s}$.