Enhanced electron injection for efficient proton acceleration and neutron production in femtosecond laser-driven nano-structured targets

TL;DR

This study demonstrates that nano-wire-array targets significantly enhance laser-driven proton and neutron production by improving electron injection, leading to higher energy conversion efficiency and neutron yields in femtosecond laser experiments.

Contribution

The paper introduces the use of nano-wire-array printed targets as efficient nano-injectors of relativistic electrons, boosting proton acceleration and neutron production beyond traditional flat targets.

Findings

Protons with energies up to 62.8 MeV were generated.

Laser-to-proton energy conversion efficiency reached 9%.

Produced 1.1×10^10 neutrons after beryllium conversion.

Abstract

Micro- or nano-structured targets are advantageous in enhancing and manipulating laser-proton acceleration, due to the increased absorption of laser energy and onset of direct laser acceleration for high-energy electrons. Here, we experimentally demonstrate that nano-wire-array printed on a flat substrate is an efficient nano-injector of relativistic electrons that leads to a significant boost of laser-driven proton acceleration and neutron production beyond normal geometry. By employing an ultra-intense (2*1021 W/cm2) femtosecond laser pulse to irradiate nano-wire-array targets, protons with cut-off energies of 62.8 MeV are generated, and notably, the energy conversion efficiency from laser to protons reaches up to 9% - 3.5 times higher than that of flat foils. After bombarding a beryllium converter, 1.1*1010 neutrons are produced. Full 3D particle-in-cell simulations have reproduced experimental results and reveal interference mechanisms between the nano-wires and substrate, leading to continuous pumping of electrons from the substrate and standing-wave enhanced re-injection from the wire tip. This efficient injection finally results in the large sheath field and thus high yield of energetic protons and neutrons. Dependence on the wire length and scaling with laser amplitude are further discussed. These results suggest that 3D-printed structures are promising in developing compact laser-driven high-flux proton and neutron sources for numerous applications.