A Markovian description of the multi-level source function and its application to the Lyman series in the Sun

• Published in: Astronomy and astrophysics (Berlin) Vol. 689; p. A239
• Main Authors: Krikova, K., Pereira, T. M. D.
• Format: Journal Article
• Language: English; Norwegian
• Published: Heidelberg EDP Sciences 01.09.2024
• Subjects: Chromosphere; Equilibrium; Equilibrium equations; Line spectra; Locking; Markov chains; Statistical methods; Stellar atmospheres
• ISSN: 0004-6361; 1432-0746
• DOI: 10.1051/0004-6361/202450506

Aims. We introduce a new method to calculate and interpret indirect transition rates populating atomic levels using Markov chain theory. Indirect transition rates are essential to evaluate interlocking in a multi-level source function, which quantifies all the processes that add and remove photons from a spectral line. A better understanding of the multi-level source function is central to interpret optically thick spectral line formation in stellar atmospheres, especially outside local thermodynamical equilibrium (LTE). Methods. We compute the level populations from a hydrogen model atom in statistical equilibrium, using the solar FALC model, a 1D static atmosphere. From the transition rates, we reconstruct the multi-level source function using our new method and compare it with existing methods to build the source function. We focus on the Lyman series lines and analyze the different contributions to the source functions and synthetic spectra. Results. Absorbing Markov chains can represent the level-ratio solution of the statistical equilibrium equation and can therefore be used to calculate the indirect transition rates between the upper and lower levels of an atomic transition. Our description of the multi-level source function allows a more physical interpretation of its individual terms, particularly a quantitative view of interlocking. For the Lyman lines in the FALC atmosphere, we find that interlocking becomes increasingly important with order in the series, with Ly- α showing very little, but Ly- β nearly 50% and Ly- γ about 60% contribution coming from interlocking. In some cases, this view seems opposed to the conventional wisdom that these lines are mostly scattering, and we discuss the reasons why. Conclusions. Our formalism to describe the multi-level source function is general and can provide more physical insight into the processes that set the line source function in a multi-level atom. The effects of interlocking for lines formed in the solar chromosphere can be more important than previously thought, and our method provides the basis for further exploration.