Analysis of a higher-energy structure in nanotip enhanced fields

We investigate strong field ionization of an atomic gas in a plasmonically enhanced field resulting from the illumination of a nanometer-sized structure with ultrafast laser pulse. We use perturbation theory to derive an approximate solution for electron's motion following ionization. These analytical estimates are corroborated by the time-dependent Schrodinger equation and classical trajectory Monte Carlo simulations. Notably, our approach can be used to obtain electron energy spectra without having to rely on numerical simulations. This allows for a deeper study of the dependence of electron energy spectrum on the properties of the near-field, suggesting electric field sensor applications. We derive an analytical expression for the location of the peak of the higher-energy structure (HES) as a function of laser parameters and near-field decay length. We find a particularly strong dependence of the energy peak on laser frequency, with lower frequencies causing a significant upward shift in the final electron energies. Combined with control of the width of the HES, which can be done by changing the size of the nanostructure, this points to the possibility of using nanotips as sources of ultrashort electron beams of tunable energy.

Automated summary

This study looks into strong field ionization of atomic gas in a plasmonically enhanced field generated by illuminating nanometer-sized structures with ultrafast laser pulses. Analytical estimates are derived using perturbation theory and corroborated by simulations, providing insights into electron energy spectrum dependence on near-field properties and suggesting electric field sensor applications. The research also presents the potential use of nanotips as sources of tunable ultrashort electron beams based on laser parameters and near-field decay length.