A hybrid simulation integrating molecular dynamics and particle-in-cell methods for improved laser-target interaction

IF 1.6 3区物理与天体物理 Q3 PHYSICS, FLUIDS & PLASMAS

High Energy Density Physics Pub Date : 2024-08-24 DOI:10.1016/j.hedp.2024.101148

Harihara Sudhan Kumar , Masayuki Takahashi , Yasuhiro Kuramitsu , Takumi Minami , Hiromitsu Kiriyama , Yuji Fukuda , Naofumi Ohnishi

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引用次数: 0

Abstract

Ultra-thin targets (less than 10 nm), such as graphene, can be irradiated with relativistic intensity lasers to generate energetic ions. However, the laser prepulse can prematurely destroy these targets and significantly influence the final ion energies. Due to the limitations of the conventional hydrodynamic model, simulating the interaction between ultra-thin targets and a prepulse is infeasible. To overcome this issue, we propose a hybrid simulation technique in this study. This technique involves simulating the target-prepulse interaction using molecular dynamics (MD) simulation, which is then combined with the particle-in-cell simulation for the target-main pulse interaction, in order to accurately model the entire laser-target interaction dynamics. A realistic, experimentally measured laser intensity profile for the prepulse is used for the MD simulation, and the particle energies from this hybrid simulation are found to be in good agreement with the experiment.

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集成分子动力学和粒子入胞法的混合模拟，用于改进激光与目标的相互作用

石墨烯等超薄目标（小于 10 纳米）可通过相对论强度激光照射产生高能离子。然而，激光预脉冲会过早地破坏这些目标，并严重影响最终离子能量。由于传统流体力学模型的局限性，模拟超薄靶和预脉冲之间的相互作用是不可行的。为了克服这一问题，我们在本研究中提出了一种混合模拟技术。该技术包括使用分子动力学（MD）模拟来模拟目标与预脉冲的相互作用，然后再结合粒子入胞模拟来模拟目标与主脉冲的相互作用，从而精确地模拟整个激光与目标相互作用的动力学过程。在 MD 模拟中使用了实验测得的真实的预脉冲激光强度曲线，结果发现这种混合模拟得出的粒子能量与实验结果非常吻合。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

High Energy Density Physics PHYSICS, FLUIDS & PLASMAS-

CiteScore

4.20

自引率

6.20%

发文量

审稿时长

6-12 weeks

期刊介绍： High Energy Density Physics is an international journal covering original experimental and related theoretical work studying the physics of matter and radiation under extreme conditions. ''High energy density'' is understood to be an energy density exceeding about 1011 J/m3. The editors and the publisher are committed to provide this fast-growing community with a dedicated high quality channel to distribute their original findings. Papers suitable for publication in this journal cover topics in both the warm and hot dense matter regimes, such as laboratory studies relevant to non-LTE kinetics at extreme conditions, planetary interiors, astrophysical phenomena, inertial fusion and includes studies of, for example, material properties and both stable and unstable hydrodynamics. Developments in associated theoretical areas, for example the modelling of strongly coupled, partially degenerate and relativistic plasmas, are also covered.