# Autoionization dynamics of He nanodroplets resonantly excited by intense   XUV laser pulses

**Authors:** Y. Ovcharenko, A. LaForge, B. Langbehn, O. Plekan, R. Cucini, P., Finetti, P.O'Keeffe, D. Iablonskyi, T. Nishiyama, K. Ueda, P. Piseri, M., DiFraia, R. Richter, M.Coreno, C.Callegari, K. C. Prince, F. Stienkemeier, T., Moller, M. Mudrich

arXiv: 1902.05332 · 2019-02-15

## TL;DR

This study investigates how helium nanodroplets of various sizes ionize under intense XUV laser pulses, revealing complex electron spectra evolution from atomic-like peaks to nanoplasma emissions, supported by detailed numerical simulations.

## Contribution

It provides a comprehensive analysis of helium droplet ionization dynamics under intense XUV irradiation, combining experimental photoelectron spectroscopy with advanced rate equation simulations.

## Key findings

- Observation of size-dependent electron spectra evolution.
- Identification of multiple ionization and relaxation processes.
- Demonstration of complex transition from atomic-like to nanoplasma emission.

## Abstract

The ionization dynamics of helium droplets in a wide size range from 220 to 10^6 He atoms irradiated with intense femtosecond extreme ultraviolet (XUV) pulses of 10^9 {\div} 10^{12} W/cm2 power density is investigated in detail by photoelectron spectroscopy. Helium droplets are resonantly excited in the photon energy range from ~ 21 eV (corresponding to the atomic 1s2s state) up to the atomic ionization potential (IP) at ~ 25 eV. A complex evolution of the electron spectra as a function of droplet size and XUV intensity is observed, ranging from atomic-like narrow peaks due to binary autoionization, to an unstructured feature characteristic of electron emission from a nanoplasma. The experimental results are analyzed and interpreted with the help of numerical simulations based on rate equations taking into account various processes such as multi-step ionization, interatomic Coulombic decay (ICD), secondary inelastic collisions, desorption of electronically excited atoms, collective autoionization (CAI) and further relaxation processes.

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Source: https://tomesphere.com/paper/1902.05332