On the critical role of the rear wall thickness of a grooved TNSA target

TL;DR

This study uses 2D PIC simulations to investigate how the rear wall thickness of a grooved TNSA target affects proton acceleration, revealing an optimal thickness for maximum energy enhancement.

Contribution

It provides new insights into the influence of rear wall thickness on proton energy spectra, highlighting the importance of precise target structuring for improved acceleration.

Findings

Proton cutoff energy increases as rear wall thickness decreases from micrometers to nanometers.

Further reduction of rear wall thickness causes a sharp drop in proton energy.

Optimal rear wall thickness exists for maximizing proton acceleration.

Abstract

The cutoff energy and the divergence of the protons generated by the target normal sheath acceleration mechanism are known to be significantly influenced by micrometer and nanometer-size structures on the target front and rear surfaces. Specifically, the cutoff energy is significantly enhanced by creating a central rectangular groove on the target front surface, as shown in a recent study [Physics of Plasmas, 30(6), 063102 (2023)]. Here we report on 2D Particle-In-Cell (PIC) simulations to thoroughly explore the effect of the depth of the central rectangular groove on the energy spectra of the accelerated protons. The proton cutoff energy is found to enhance drastically as the thickness of the rear wall of the groove is reduced from a few micrometers to a few tens of nanometers, however, it drops sharply as the thickness of the rear wall is further reduced towards creating a complete hole through the target.