Magnetic Field of Solar Dark Filaments Obtained from He I 10830 Angstrom Spectro-polarimetric Observation

Solar filaments are dense and cool plasma clouds in the solar corona. They are supposed to be supported in a dip of coronal magnetic field. However, the models are still under argument between two types of the field configuration; one is the normal polarity model proposed by Kippenhahn & Schluet...

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Veröffentlicht in:	arXiv.org 2023-04
Hauptverfasser:	Yamasaki, Daiki, Yu Wei Huang, Hashimoto, Yuki, Cabezas, Denis P, Kawate, Tomoko, UeNo, Satoru, Ichimoto, Kiyoshi
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Sprache:	eng
Schlagworte:	Filaments Magnetic field configurations Magnetic fields Magnetic structure Photosphere Physics - Solar and Stellar Astrophysics Plasma clouds Polarimetry Solar corona Solar magnetic field
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creator	Yamasaki, Daiki Yu Wei Huang Hashimoto, Yuki Cabezas, Denis P Kawate, Tomoko UeNo, Satoru Ichimoto, Kiyoshi
description	Solar filaments are dense and cool plasma clouds in the solar corona. They are supposed to be supported in a dip of coronal magnetic field. However, the models are still under argument between two types of the field configuration; one is the normal polarity model proposed by Kippenhahn & Schlueter (1957), and the other is the reverse polarity model proposed by Kuperus & Raadu (1974). To understand the mechanism that the filaments become unstable before the eruption, it is critical to know the magnetic structure of solar filaments. In this study, we performed the spectro-polarimetric observation in the He I (10830 angstrom) line to investigate the magnetic field configuration of dark filaments. The observation was carried out with the Domeless Solar Telescope at Hida Observatory with a polarization sensitivity of 3.0x10^-4. We obtained 8 samples of filaments in quiet region. As a result of the analysis of full Stokes profiles of filaments, we found that the field strengths were estimated as 8 - 35 Gauss. By comparing the direction of the magnetic field in filaments and the global distribution of the photospheric magnetic field, we determined the magnetic field configuration of the filaments, and we concluded that 1 out of 8 samples have normal polarity configuration, and 7 out of 8 have reverse polarity configuration.
doi_str_mv	10.48550/arxiv.2304.00422
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subjects	Filaments Magnetic field configurations Magnetic fields Magnetic structure Photosphere Physics - Solar and Stellar Astrophysics Plasma clouds Polarimetry Solar corona Solar magnetic field
title	Magnetic Field of Solar Dark Filaments Obtained from He I 10830 Angstrom Spectro-polarimetric Observation
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