Temporal and spectral disentanglement of laser-driven electron tunneling emission from a solid

TL;DR

This study investigates laser-driven electron emission from a tungsten tip, revealing a new emission channel involving tunneling and re-scattering, which enhances understanding of attosecond processes and aids in designing pulsed electron sources.

Contribution

It demonstrates the disentanglement of laser-driven tunneling and photo-excited emissions both temporally and spectrally, introducing a novel emission channel involving re-scattering.

Findings

Confirmation of laser-driven tunneling emission in strong fields

Identification of a new emission channel involving re-scattering

Insights into attosecond electron emission from solids

Abstract

By measuring energy spectra of the electron emission from a sharp tungsten tip induced by few-cycle laser pulses, the laser-field dependence of the emission mechanism was investigated. In strong laser fields, we confirm the appearance of laser-driven tunneling emission and find that it can be disentangled from the concomitant photo-excited electron emission, both temporally and spectrally, by the opening of a peculiar emission channel. This channel involves prompt laser-driven tunneling emission and subsequent laser-driven electron re-scattering off the surface, delayed by the electrons traveling far inside the metal before scattering. The quantitative understanding of these processes gives insights on attosecond tunneling emission from solids and should prove useful in designing new types of pulsed electron sources.