Electron inelastic mean free paths in condensed matter down to a few electronvolts

TL;DR

This paper presents a reliable method for calculating electron inelastic mean free paths across a wide energy range in various condensed matter materials, with results matching experimental data, especially at low energies critical for radiobiology and nanotechnology.

Contribution

It introduces a simple, accurate calculation method for low to high energy electron mean free paths, improving understanding of electron transport in materials.

Findings

Excellent agreement with experimental data for water, aluminum, gold, and copper.

Accurate predictions at very low electron energies.

Provides insights into low energy electron effects in biological and nanostructured systems.

Abstract

A method is reported for a simple, yet reliable, calculation of electron inelastic mean free paths in condensed phase insulating and conducting materials, from the very low energies of hot electrons up to the high energies characteristic of electron beams. Through a detailed consideration of the energy transferred by the projectile in individual and collective electronic excitations, as well as ionizations, together with the inclusion of higher order corrections to the results provided by the dielectric formalism, inelastic mean free paths are calculated for water, aluminum, gold and copper in excellent agreement with the available experimental data, even at the elusive very low energy region. These results are important due to the crucial role played by low energy electrons in radiobiology (owing to their relevant effects in biodamage), and also in order to assess the not yet elucidated disagreement between older and recent measurements of low energy electron mean free paths in metals (which are relevant for low energy electron transport and effects in nanostructured devices).