Acceleration of protons to high energies by an ultra-intense femtosecond laser pulse

TL;DR

This study uses 2D particle-in-cell simulations to demonstrate that ultra-intense femtosecond laser pulses can accelerate protons to GeV energies, producing extremely short, high-intensity proton beams with potential applications in physics and materials research.

Contribution

The paper presents new simulation results showing efficient proton acceleration to GeV energies using ultra-intense laser pulses, highlighting effects of polarization and target thickness.

Findings

Protons reach about 2 GeV energy at 10^23 W/cm^2 intensity.

Proton beams are ultra-short (<20 fs) and highly intense (>10^21 W/cm^2).

Laser polarization has a weak effect at ultra-relativistic intensities.

Abstract

The paper reports the results of two-dimensional particle-in-cell simulations of proton beam acceleration at the interactions of a 130 fs laser pulse of intensity from the range of 10^21-10^23 W/cm^2, predicted for the Extreme Light Infrastructure (ELI) lasers currently built in Europe, with a thin hydrocarbon (CH) target. A special attention is paid to the effect of the laser pulse intensity and polarization (linear-LP, circular-CP) as well as the target thickness on the proton energy spectrum, the proton beam spatial distribution and the proton pulse shape and intensity. It is shown that for the highest, ultra-relativistic intensities (10^23 W/cm^2) the effect of laser polarization on the proton beam parameters is relatively weak and for both polarizations quasi-monoenergetic proton beams of the mean proton energy about 2 GeV and dE/E=0.3 for LP and dE/E=0.2 for CP are generated from the 0.1 micrometer CH target. At short distances from the irradiated target (below 50 micrometers), the proton pulse is very short (below 20 fs), and the proton beam intensities reach extremely high values above 10^21 W/cm^2, which are much higher than those attainable in conventional accelerators. Such proton beams can open the door for new areas of research in high energy-density physics and nuclear physics as well as can also prove useful for applications in materials research e.g. as a tool for high-resolution proton radiography.