Simulation of spectral observations of an eruptive prominence

Yu. A. Kupryakov; Купряков Ю. А.; K. V. Bychkov; Бычков К. В.; O. M. Belova; Белова О. М.; A. B. Gorshkov; Горшков А. Б.; P. Kotrč; Котрч П.

doi:10.31857/S0016794024010031

Simulation of spectral observations of an eruptive prominence

Autores: Kupryakov Y.A.¹^,2, Bychkov K.V.², Belova O.M.², Gorshkov A.B.², Kotrč P.¹
Afiliações:
1. ASCR
2. Moscow State University
Edição: Volume 64, Nº 1 (2024)
Páginas: 23-28
Seção: Articles
URL: https://ogarev-online.ru/0016-7940/article/view/260739
DOI: https://doi.org/10.31857/S0016794024010031
EDN: https://elibrary.ru/GREFDK
ID: 260739

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The paper presents the results of an analysis of observations of an eruptive prominence on the MFS and HSFA2 spectrographs of the Ondřejov Observatory (Astronomical Institute, Czech Republic) in the lines of hydrogen, helium and calcium. After processing the spectra, the integral radiation fluxes in the lines were determined and a theoretical calculation of the physical parameters of the plasma was carried out using a model in the absence of local thermodynamic equilibrium. A comparison of the observed and calculated values showed that the observed radiation fluxes in the lines can be explained in a model of stationary gas radiation taking into account the opacity in the spectral lines. To calculate theoretical fluxes, in some cases it was necessary to introduce radiation from several layers with different temperatures and heights. The calculated radiation fluxes agree with the observed ones with an accuracy of 10%. As a result of the simulation, the main parameters of the prominence plasma were obtained: temperature, concentration, etc. The values of radiation fluxes in the spectral lines indicate the inhomogeneity of the emitting gas, and there may be regions next to each other whose temperatures differ by an order of magnitude.

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Sobre autores

Yu. Kupryakov

ASCR; Moscow State University

Email: jurij.kupriakov@asu.cas.cz

Astronomical Institute, Sternberg Astronomical Institute

Tchéquia, Ondřejov; Russia, Moscow

K. Bychkov

Moscow State University

Email: bychkov@sai.msu.ru

Sternberg Astronomical Institute

Rússia, Moscow

O. Belova

Moscow State University

Email: whitecanvas05122010@mail.ru

Sternberg Astronomical Institute

Rússia, Moscow

A. Gorshkov

Moscow State University

Email: gorshkov@sai.msu.ru

Sternberg Astronomical Institute

Rússia, Moscow

P. Kotrč

ASCR

Autor responsável pela correspondência
Email: pavel.kotrc@asu.cas.cz

Astronomical Institute

Tchéquia, Ondřejov

Bibliografia

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Вайнштейн Л.А., Собельман И.И., Юков Е.А. Сечения возбуждения атомов и ионов электронами. М.: Наука, 142 с. 1973.
Anzer U., Heinzel P. Prominence Parameters Derived from Magnetic-Field Measurements and NLTE Diagnostics // Sol. Phys. V. 179. № 1. P. 75–87. 1998. https://doi.org/10.1023/A:1005000616138
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Schwartz P., Balthasar H., Kuckein C., et al. NLTE modeling of a small active region filament observed with the VTT // Astron. Nachr. V. 337. № 10. P. 1045—1049. 2016. https://doi.org/10.1002/asna.201612431
Schwartz P., Gunár S., Jenkins J.M., et al. 2D non-LTE modelling of a filament observed in the Hα line with the DST/IBIS spectropolarimeter // A&A. V. 631. P. A146 (12P). 2019.
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2. Fig. 1. Hα spectrum at 13:21:11 UT (left). The numbers correspond to photometric sections. Below is the speed scale. In the center is the image on the slit in the Hα line. On the right is an image of SDO 304 Å with the spectrograph slit position and Doppler velocity components marked.