Communications Physics (Dec 2023)

Time-resolved optical shadowgraphy of solid hydrogen jets as a testbed to benchmark particle-in-cell simulations

  • Long Yang,
  • Lingen Huang,
  • Stefan Assenbaum,
  • Thomas E. Cowan,
  • Ilja Goethel,
  • Sebastian Göde,
  • Thomas Kluge,
  • Martin Rehwald,
  • Xiayun Pan,
  • Ulrich Schramm,
  • Jan Vorberger,
  • Karl Zeil,
  • Tim Ziegler,
  • Constantin Bernert

DOI
https://doi.org/10.1038/s42005-023-01473-w
Journal volume & issue
Vol. 6, no. 1
pp. 1 – 15

Abstract

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Abstract Particle-in-cell (PIC) simulations are a widely-used tool to model kinetics-dominated plasmas in ultrarelativistic laser-solid interactions (dimensionless vectorpotential a 0 > 1). However, interactions approaching subrelativistic laser intensities (a 0 ≲ 1) are governed by correlated and collisional plasma physics, calling for benchmarks of available modeling capabilities and the establishment of standardized testbeds. Here, we propose such a testbed to experimentally benchmark PIC simulations of laser-solid interactions using a laser-irradiated micron-sized cryogenic hydrogen-jet target. Time-resolved optical shadowgraphy of the expanding plasma density, complemented by hydrodynamics and ray-tracing simulations, is used to determine the bulk-electron-temperature evolution after laser irradiation. We showcase our testbed by studying isochoric heating of solid hydrogen induced by laser pulses with a dimensionless vectorpotential of a 0 ≈ 1. Our testbed reveals that the initial surface-density gradient of the target is decisive to reach quantitative agreement at 1 ps after the interaction, demonstrating its suitability to benchmark controlled parameter scans at subrelativistic laser intensities.