High Dose-Rate Ionizing Radiation Source from Tight Focusing in Air of a mJ-class Femtosecond Laser

TL;DR

This paper demonstrates a simple method to generate high-energy electron beams in air using a femtosecond laser, achieving dose rates that surpass safety limits and offering potential for medical radiation therapy.

Contribution

It introduces a novel, straightforward technique for producing MeV electron beams in air with femtosecond lasers, supported by simulations and scalable for future high-power laser systems.

Findings

Achieved dose rate of 0.15 Gy/s at one meter from the source.

Confirmed acceleration mechanism via Particle-In-Cell simulations.

Potential application in FLASH radiation therapy.

Abstract

Ultrashort electron beams with femtosecond to picosecond bunch durations offer unique opportunities to explore active research areas ranging from ultrafast structural dynamics to ultra-high dose-rate radiobiological studies. We present a straightforward method to generate MeV-ranged electron beams in ambient air through the tight focusing of a few-cycle, mJ-class femtosecond IR laser. At one meter from the source, the highest measured dose rate of 0.15 Gy/s exceeds the yearly dose limit in less than one second and warrants the implementation of radiation protection. Two-dimensional Particle-In-Cell simulations confirm that the acceleration mechanism is based on the relativistic ponderomotive force and show theoretical agreement with the measured electron energy. Furthermore, we discuss the scalability of this method with the continuing development of mJ-class high average power lasers, moreover providing a promising approach for FLASH radiation therapy.