Investigating Self-Induced Relativistic Transparency in Plasmas with Ultrafast High Intensity Laser Pulses

Brendan Stassel; Brandon Russell; Paul T. Campbell; Hongmei Tang; Anatoly Maksimchuk; Louise Willingale

Investigating Self-Induced Relativistic Transparency in Plasmas with Ultrafast High Intensity Laser Pulses

POSTER

Abstract

We model high intensity laser plasma interactions on thin film and solid targets to study the self-induced relativistic transparency regime. The 2D OSIRIS 4.0 particle-in-cell simulations were designed to model the HERCULES laser pulse. The wavelength $\lambda$ was 800 nm, pulse duration was 30 fs, and the normalized vector potential $a_0$ was varied between 0.5 and 30. Also, the target thickness was varied between 50 nm and 200 nm. In preparation for experiments with HERCULES, an analysis of the data is presented along with a study of the transmitted and reflected laser characteristics, and electron spectra.

^*This material is based upon work supported by the Department of Energy under Award Number DE-SC0020236.

Authors

Brendan Stassel
- Univ of Michigan - Ann Arbor
Brandon Russell
- University of Michigan
- Univ of Michigan - Ann Arbor
Paul T. Campbell
- University of Michigan
- Univ of Michigan - Ann Arbor
Hongmei Tang
- University of Michigan
- Univ of Michigan - Ann Arbor
Anatoly Maksimchuk
- Univ of Michigan - Ann Arbor
- University of Michigan, Gérard Mourou Center of Ultrafast Optical Science, Ann Arbor, Michigan 48109
- University of Michigan
- University of Michigan, Ann Arbor
Louise Willingale
- University of Michigan
- Univ of Michigan - Ann Arbor