Deep learning surrogate models to solve time-dependent NLTE absorption and emission spectra

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

High Energy Density Physics Pub Date : 2025-04-30 DOI:10.1016/j.hedp.2025.101199

Jingsong Zhang , Wengu Chen , Xiaoying Han , Peng Song , Han Wang

引用次数: 0

Abstract

Non-local thermodynamic equilibrium (NLTE) absorption and emission spectra are crucial in indirect drive inertial confinement fusion (ICF) simulations. Meanwhile, they are one of the most computationally expensive parts in ICF simulations. In some special physics scenarios, we need to calculate non-stationary ion states instead of stationary ones in NLTE problems. Although previous works have developed some effective methods to calculate stationary states of plasmas in NLTE conditions, they cannot be directly used for calculating non-stationary states. In this paper we propose a deep learning surrogate model method to solve time-dependent NLTE spectra. This new method fits data generated by time-dependent radiation-hydrodynamics simulations quite well and achieves about tens to hundreds of times acceleration on Average Atom Model (AAM) and about twenty to fifty thousand times acceleration on Multi-Average Ion Collisional-Radiative Model (MAICRM) respectively.

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求解随时间变化的NLTE吸收和发射光谱的深度学习代理模型

非局部热力学平衡（NLTE）的吸收和发射光谱是间接驱动惯性约束聚变（ICF）模拟的关键。同时，它们是ICF模拟中计算成本最高的部分之一。在一些特殊的物理场景中，我们需要计算非稳态离子态，而不是NLTE问题中的稳态离子态。虽然前人的工作已经开发出一些有效的方法来计算NLTE条件下等离子体的稳态，但它们不能直接用于计算非稳态。本文提出了一种求解随时间变化的NLTE频谱的深度学习代理模型方法。该方法较好地拟合了随时间变化的辐射-流体动力学模拟数据，在平均原子模型（AAM）和多平均离子碰撞-辐射模型（MAICRM）上分别实现了数十至数百倍和20至5万倍的加速。

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.