# Parametric dependence of hot electron relaxation timescales on   electron-electron and electron-phonon interaction strengths

**Authors:** Richard Wilson, Sinisa Coh

arXiv: 1906.11397 · 2020-10-23

## TL;DR

This paper derives simple expressions showing how electron-electron and electron-phonon interactions influence hot electron relaxation times across metals, revealing universal and counterintuitive dependencies.

## Contribution

It introduces analytical formulas capturing the interplay of e-e and e-p interactions on electron relaxation times, highlighting their universal and counterintuitive effects.

## Key findings

- e-e and e-p interactions jointly influence relaxation times
- e-p interactions reduce total excited electron energy
- e-e interactions affect high-energy electron occupancy duration

## Abstract

Understanding how photoexcited electron dynamics depend on electron-electron (e-e) and electron-phonon (e-p) interaction strengths is important for many fields, e.g. ultrafast magnetism, photocatalysis, plasmonics, and others. Here, we report simple expressions that capture the interplay of e-e and e-p interactions on electron distribution relaxation times. We observe a dependence of the dynamics on e-e and e-p interaction strengths that is universal to most metals and is also counterintuitive. While only e-p interactions reduce the total energy stored by excited electrons, the time for energy to leave the electronic subsystem also depends on e-e interaction strengths because e-e interactions increase the number of electrons emitting phonons. The effect of e-e interactions on energy-relaxation is largest in metals with strong e-p interactions. Finally, the time high energy electron states remain occupied depends only on the strength of e-e interactions, even if e-p scattering rates are much greater than e-e scattering rates.

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Source: https://tomesphere.com/paper/1906.11397