Kinetic PIC simulations identify a non-quasi-neutral charge-separation double layer as the dominant ion acceleration mechanism in laser-driven cryogenic hydrogen targets, which is suppressed by kT-scale axial magnetic fields that also extend compression time.
Scaling of thin wire cylindrical compression after 100 fs Joule surface heating with material, diameter and laser energy, 2025, [arXiv:physics.plasm-ph/2507.12109]
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Time-resolved resonant X-ray absorption and emission spectroscopy diagnoses ultrafast heating and ionization dynamics in laser-solid interactions, with multi-scale simulations constraining plasma parameters via detailed laser and pre-plasma accounting.
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Kinetic Simulations of Laser-Driven Compression and Heating of Magnetised Cryogenic Hydrogen Targets using PIConGPU
Kinetic PIC simulations identify a non-quasi-neutral charge-separation double layer as the dominant ion acceleration mechanism in laser-driven cryogenic hydrogen targets, which is suppressed by kT-scale axial magnetic fields that also extend compression time.
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Probing ultrafast heating and ionization dynamics in solid density plasmas with time-resolved resonant X-ray absorption and emission
Time-resolved resonant X-ray absorption and emission spectroscopy diagnoses ultrafast heating and ionization dynamics in laser-solid interactions, with multi-scale simulations constraining plasma parameters via detailed laser and pre-plasma accounting.