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Main Authors: da Silva, Ricardo Ferreira, Flörs, Andreas, Leitão, Luís, Marques, José P., Martínez-Pinedo, Gabriel, Sampaio, Jorge M.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2502.13250
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author da Silva, Ricardo Ferreira
Flörs, Andreas
Leitão, Luís
Marques, José P.
Martínez-Pinedo, Gabriel
Sampaio, Jorge M.
author_facet da Silva, Ricardo Ferreira
Flörs, Andreas
Leitão, Luís
Marques, José P.
Martínez-Pinedo, Gabriel
Sampaio, Jorge M.
contents This study presents a novel optimisation technique for atomic structure calculations using the Flexible Atomic Code, focussing on complex multielectron systems relevant to $r$-process nucleosynthesis and kilonova modelling. We introduce a method to optimise the fictitious mean configuration used in the Flexible Atomic Code, significantly improving the accuracy of calculated energy levels and transition properties for lanthanide and actinide ions. Our approach employs a Sequential Model-Based Optimisation algorithm to refine the fictitious mean configuration, iteratively minimising the discrepancy between calculated and experimentally determined energy levels. We demonstrate the efficacy of this method through detailed analyses of Au II, Pt II, Pr II, Pr III, Er II, and Er~III, representing a broad range of atomic configurations. The results show substantial improvements in the accuracy of the calculated energy levels, with average relative differences to the NIST data reduced from 20-60\% to 10\% or less for the ions studied. Transition wavelength calculations exhibit exceptional agreement with experimental data, with about 90\% of the calculated values falling within 10\% of measurements for Pr and Er ions. While improvements in transition probability calculations are observed, the calculated transition probabilities (log($gf$) values) still show significant discrepancies compared to the experimental data, with root mean square deviations of approximately 1.1-1.4 dex for Pr and Er ions. We extend our optimisation technique to systematic calculations of singly and doubly ionised lanthanides, achieving accuracies comparable to or surpassing those of \textit{ab-initio} atomic structure codes. The method's broad applicability across the lanthanide series demonstrates its potential for enhancing opacity calculations and spectral modelling in astrophysical contexts.
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id arxiv_https___arxiv_org_abs_2502_13250
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publishDate 2025
record_format arxiv
spellingShingle Systematic Bayesian Optimization for Atomic Structure Calculations of Heavy Elements
da Silva, Ricardo Ferreira
Flörs, Andreas
Leitão, Luís
Marques, José P.
Martínez-Pinedo, Gabriel
Sampaio, Jorge M.
Atomic Physics
High Energy Astrophysical Phenomena
This study presents a novel optimisation technique for atomic structure calculations using the Flexible Atomic Code, focussing on complex multielectron systems relevant to $r$-process nucleosynthesis and kilonova modelling. We introduce a method to optimise the fictitious mean configuration used in the Flexible Atomic Code, significantly improving the accuracy of calculated energy levels and transition properties for lanthanide and actinide ions. Our approach employs a Sequential Model-Based Optimisation algorithm to refine the fictitious mean configuration, iteratively minimising the discrepancy between calculated and experimentally determined energy levels. We demonstrate the efficacy of this method through detailed analyses of Au II, Pt II, Pr II, Pr III, Er II, and Er~III, representing a broad range of atomic configurations. The results show substantial improvements in the accuracy of the calculated energy levels, with average relative differences to the NIST data reduced from 20-60\% to 10\% or less for the ions studied. Transition wavelength calculations exhibit exceptional agreement with experimental data, with about 90\% of the calculated values falling within 10\% of measurements for Pr and Er ions. While improvements in transition probability calculations are observed, the calculated transition probabilities (log($gf$) values) still show significant discrepancies compared to the experimental data, with root mean square deviations of approximately 1.1-1.4 dex for Pr and Er ions. We extend our optimisation technique to systematic calculations of singly and doubly ionised lanthanides, achieving accuracies comparable to or surpassing those of \textit{ab-initio} atomic structure codes. The method's broad applicability across the lanthanide series demonstrates its potential for enhancing opacity calculations and spectral modelling in astrophysical contexts.
title Systematic Bayesian Optimization for Atomic Structure Calculations of Heavy Elements
topic Atomic Physics
High Energy Astrophysical Phenomena
url https://arxiv.org/abs/2502.13250