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.
Exact charge conservation scheme for Particle-in-Cell simulation with an arbitrary form-factor.Computer Physics Communications2001,135, 144–153
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Entity PIC code updated with up to 11th-order current deposit and generalized field stencils, with tests showing improved conservation properties and suppression of numerical effects.
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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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Entity -- Hardware-agnostic Particle-in-Cell Code for Plasma Astrophysics. III: Higher-order shape functions & generalized field stencils
Entity PIC code updated with up to 11th-order current deposit and generalized field stencils, with tests showing improved conservation properties and suppression of numerical effects.