Matter and Radiation at Extremes (Nov 2022)

High-energy-density plasma in femtosecond-laser-irradiated nanowire-array targets for nuclear reactions

  • Defeng Kong,
  • Guoqiang Zhang,
  • Yinren Shou,
  • Shirui Xu,
  • Zhusong Mei,
  • Zhengxuan Cao,
  • Zhuo Pan,
  • Pengjie Wang,
  • Guijun Qi,
  • Yao Lou,
  • Zhiguo Ma,
  • Haoyang Lan,
  • Wenzhao Wang,
  • Yunhui Li,
  • Peter Rubovic,
  • Martin Veselsky,
  • Aldo Bonasera,
  • Jiarui Zhao,
  • Yixing Geng,
  • Yanying Zhao,
  • Changbo Fu,
  • Wen Luo,
  • Yugang Ma,
  • Xueqing Yan,
  • Wenjun Ma

DOI
https://doi.org/10.1063/5.0120845
Journal volume & issue
Vol. 7, no. 6
pp. 064403 – 064403-12

Abstract

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In this work, the high-energy-density plasmas (HEDP) evolved from joule-class-femtosecond-laser-irradiated nanowire-array (NWA) targets were numerically and experimentally studied. The results of particle-in-cell simulations indicate that ions accelerated in the sheath field around the surfaces of the nanowires are eventually confined in a plasma, contributing most to the high energy densities. The protons emitted from the front surfaces of the NWA targets provide rich information about the interactions that occur. We give the electron and ion energy densities for broad target parameter ranges. The ion energy densities from NWA targets were found to be an order of magnitude higher than those from planar targets, and the volume of the HEDP was several-fold greater. At optimal target parameters, 8% of the laser energy can be converted to confined protons, and this results in ion energy densities at the GJ/cm3 level. In the experiments, the measured energy of the emitted protons reached 4 MeV, and the changes in energy with the NWA’s parameters were found to fit the simulation results well. Experimental measurements of neutrons from 2H(d,n)3He fusion with a yield of (24 ± 18) × 106/J from deuterated polyethylene NWA targets also confirmed these results.