Modeling Mg ii during Solar Flares. II. Nonequilibrium Effects

To extract the information that the Mg ii NUV spectra (observed by the Interface Region Imaging Spectrograph) carry about the chromosphere during solar flares, and to validate models of energy transport via model-data comparison, forward modeling is required. The assumption of statistical equilibriu...

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Bibliographic Details
Published in:The Astrophysical journal 2019-11, Vol.885 (2), p.119
Main Authors: Kerr, Graham S., Carlsson, Mats, Allred, Joel C.
Format: Article
Language:English
Subjects:
Active solar chromosphere
Astrophysics
Chromosphere
Computational methods
Computer simulation
Data comparison
Energy transport
Equilibrium
Ionization
Near ultraviolet astronomy
Populations
Radiation
Radiative transfer
Radiative transfer simulations
Solar chromosphere
Solar flare spectra
Solar flares
Solar Physics
Time dependence
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Summary:To extract the information that the Mg ii NUV spectra (observed by the Interface Region Imaging Spectrograph) carry about the chromosphere during solar flares, and to validate models of energy transport via model-data comparison, forward modeling is required. The assumption of statistical equilibrium (SE) is typically used to obtain the atomic level populations from snapshots of flare atmospheres, due to computational necessity. However, it is possible that relying on SE could lead to spurious results. We compare solving the atomic level populations via SE versus a nonequilibrium (NEQ) time-dependent approach. This was achieved using flare simulations from RADYN alongside the minority species version MS_RADYN from which the time-dependent Mg ii atomic level populations and radiation transfer were computed in complete frequency redistribution. The impacts on the emergent profiles, lightcurves, line ratios, and formation heights are discussed. In summary we note that NEQ effects during flares are typically important only in the initial stages and for a short period following the cessation of the energy injection. An analysis of the timescales of ionization equilibrium reveals that for most of the duration of the flare, when the temperatures and densities are sufficiently enhanced, the relaxation timescales are short (τrelax < 0.1 s), so that the equilibrium solution is an adequate approximation. These effects vary with the size of the flare, however. In weaker flares, effects can be more pronounced. We recommend that NEQ effects be considered when possible but that SE is sufficient at most stages of the flare.
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/ab48ea