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Hauptverfasser: Wu, Chao, Xia, Wen Hao, Wu, Yong, Yan, Jun, Li, Ming, Wang, Jian Guo, Gao, Xiang
Format: Preprint
Veröffentlicht: 2026
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2601.19538
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author Wu, Chao
Xia, Wen Hao
Wu, Yong
Yan, Jun
Li, Ming
Wang, Jian Guo
Gao, Xiang
author_facet Wu, Chao
Xia, Wen Hao
Wu, Yong
Yan, Jun
Li, Ming
Wang, Jian Guo
Gao, Xiang
contents Electron-atom collisions in warm dense plasmas are crucial for astrophysics and controlled fusion research, where calculating short-range scattering matrices under screening plasma potentials is essential. While electron-neutral atom collisions are tractable using the standard Riccati-Bessel wavefunctions in the asymptotic region, electron-ion collisions face challenges due to the extended range of the screened Coulomb potential, which lacks analytical solutions or numerical code packages for asymptotic regular and irregular wavefunctions. We introduce an R-matrix theoretical framework for general screened potentials and develop a numerical method to compute these asymptotic wavefunctions efficiently. Our approach yields short-range scattering phase shifts that remain invariant with respect to the matching point in the asymptotic region. Applying the Debye screening potential as an illustrative example, we calculate elastic and electron-impact excitation collision strengths for H-like ions (He, C, Ne) across varying temperatures and densities. The calculations show that Debye screening systematically modifies resonance structures and progressively lowers excitation thresholds. Nevertheless, the effective collision strengths and rate coefficients exhibit approximate scaling laws. These findings enable convenient access to electron collision data in plasma environments, advancing plasma diagnostics and modeling.
format Preprint
id arxiv_https___arxiv_org_abs_2601_19538
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle R-Matrix Theory for Electron-Ion Collisions in Plasmas
Wu, Chao
Xia, Wen Hao
Wu, Yong
Yan, Jun
Li, Ming
Wang, Jian Guo
Gao, Xiang
Atomic Physics
Electron-atom collisions in warm dense plasmas are crucial for astrophysics and controlled fusion research, where calculating short-range scattering matrices under screening plasma potentials is essential. While electron-neutral atom collisions are tractable using the standard Riccati-Bessel wavefunctions in the asymptotic region, electron-ion collisions face challenges due to the extended range of the screened Coulomb potential, which lacks analytical solutions or numerical code packages for asymptotic regular and irregular wavefunctions. We introduce an R-matrix theoretical framework for general screened potentials and develop a numerical method to compute these asymptotic wavefunctions efficiently. Our approach yields short-range scattering phase shifts that remain invariant with respect to the matching point in the asymptotic region. Applying the Debye screening potential as an illustrative example, we calculate elastic and electron-impact excitation collision strengths for H-like ions (He, C, Ne) across varying temperatures and densities. The calculations show that Debye screening systematically modifies resonance structures and progressively lowers excitation thresholds. Nevertheless, the effective collision strengths and rate coefficients exhibit approximate scaling laws. These findings enable convenient access to electron collision data in plasma environments, advancing plasma diagnostics and modeling.
title R-Matrix Theory for Electron-Ion Collisions in Plasmas
topic Atomic Physics
url https://arxiv.org/abs/2601.19538