Absorption of High Intensity, High Contrast Femtosecond Laser Pulses by a Solid

TL;DR

This study experimentally investigates high-intensity femtosecond laser absorption in fused silica, revealing near 80% energy absorption at optimal angles, which is significant for plasma mirror applications and understanding laser-matter interactions.

Contribution

It provides the first detailed experimental analysis of laser absorption at near-relativistic intensities in solids, highlighting collisionless processes and optimal angles for maximum absorption.

Findings

Up to 80% laser energy absorption at optimal angles.

High reflectivity at smaller angles indicates relevance for plasma mirrors.

Absorption depends strongly on angle and polarization.

Abstract

The basic understanding of high-intensity femtosecond laser absorption in a solid is crucial for high-energy-density science. This multidimensional problem has many variables like laser parameters, solid target material, and geometry of the excitation. This is important for a basic understanding of intense laser-matter interaction as well for applications such as `plasma mirror'. Here, we have experimentally observed high-intensity, high-contrast femtosecond laser absorption by an optically polished fused silica target at near-relativistic laser intensities ($\sim$10$^{18}$ W/cm$^2$). The laser absorption as a function of angle of incidence and incident energy is investigated for both $p$- and $s$-polarized pulses in detail, providing a strong indication of the presence of collisionless processes. At an optimum angle of incidence, almost as large as 80% of the laser ($p$-polarized) energy gets absorbed in the target. Such a high percentage of absorption at near-relativistic intensities has not been observed before. At smaller angles of incidence the high reflectivity (e.g. about 60 - 70% at 30$^\circ$ incidence) indicate that, this study is fundamentally relevant for plasma mirrors at near-relativistic intensities.