Physics-Informed Latent Space Dynamics Identification for Time-Dependent NLTE Atomic Kinetics
Abstract
Non-local thermodynamic equilibrium (NLTE) calculations remain a major computational bottleneck in radiation--hydrodynamics, while most existing machine-learning surrogates treat NLTE as a static input--output mapping rather than a kinetic evolution problem. Here, we present a physics-informed Latent Space Dynamics Identification (pLaSDI) framework specifically designed for NLTE atomic kinetics, which captures the time-dependent atomic kinetics of non-equilibrium plasmas through an explicit reduced governing equation. To ensure the physical reliability of the reduced model, we impose physics-informed loss terms that enforce macroscopic consistency, dynamical stability, and convergence to the correct steady state during long-time integration. Applied to tin NLTE population data generated along hydrodynamically modeled temperature--density trajectories relevant to extreme ultraviolet (EUV) lithography plasmas, the model accurately reproduces charge-state evolution and mean charge state with errors below 2\%, achieves speedups of approximately --, and remains stable outside the training trajectories by converging toward physically admissible states and the correct steady-state solution under fixed plasma conditions. These results show that careful physics-informed design of the latent dynamics, rather than data fitting alone, is essential for constructing fast, stable, and physically reliable extrapolative surrogates for time-dependent NLTE kinetics.
Keywords
Cite
@article{arxiv.2604.16664,
title = {Physics-Informed Latent Space Dynamics Identification for Time-Dependent NLTE Atomic Kinetics},
author = {Jeongwoo Nam and William Anderson and Youngsoo Choi and Hai P. Le and Mark E. Foord and Byoung Ick Cho and Haewon Jeong and Min Sang Cho},
journal= {arXiv preprint arXiv:2604.16664},
year = {2026}
}
Comments
28 pages, 7 figures