Characteristics of solar microflares as seen in soft X-ray emission

In this paper, we present the thermal and non-thermal characteristics of solar plasma producing microflares in 4–12 keV energy range. The X-ray spectra of 10 B-class solar microflares observed by the silicon (Si) detector (4–25 keV) on-board solar X-ray spectrometer (SOXS) mission were analysed in 4...

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Bibliographic Details
Published in:Pramāṇa 2019-03, Vol.92 (3), p.1-11, Article 32
Main Authors: Kumar, Pramod, Jain, R, Bhatt, Y C, Shishodia, Y S
Format: Article
Language:English
Subjects:
Astronomy
Astrophysics and Astroparticles
Atmospheric models
Conduction cooling
Conduction heating
Cooling
Crossovers
Differential thermal analysis
High temperature
Mathematical models
Observations and Techniques
Order parameters
Physics
Physics and Astronomy
Plasma
Plasma temperature
Power law
Silicon
Soft x rays
Solar activity
Solar observatories
Thermal energy
Time lag
X ray spectra
X ray spectrometers
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Summary:In this paper, we present the thermal and non-thermal characteristics of solar plasma producing microflares in 4–12 keV energy range. The X-ray spectra of 10 B-class solar microflares observed by the silicon (Si) detector (4–25 keV) on-board solar X-ray spectrometer (SOXS) mission were analysed in 4–12 keV energy range. We employed forward fitting for the spectral modelling of thermal and non-thermal components of X-ray spectra with isothermal, multithermal and single power-law functions in order to determine flare parameters. The fit results obtained from the combination of isothermal and single power-law functions yield a weighted mean value of emission measure ( EM ) ≈ 0.0203 × 10 49 cm - 3 , plasma temperature [Case (1)] T ( 1 ) ≈ 10.24 MK and non-thermal spectral index γ ( 1 ) ≈ 3.90 . The fit results obtained from the combination of multithermal and single power-law functions yield a weighted mean value of differential emission measure, ( DEM ) ≈ 0.00116 × 10 49 cm - 3 keV - 1 , plasma temperature [Case (2)], T ( 2 ) ≈ 12.90 MK , thermal spectral index, δ ≈ 4.06 and non-thermal spectral index, γ ( 2 ) ≈ 3.81 . Further, we obtained the mean value of conduction cooling time, τ c ( T ) ≈ 283 s at 11.6 MK, thermal energy, E th ≈ 0.50 × 10 29 erg and thermal–non-thermal cross-over energy, ϵ th ≈ 9.23 keV. In this analysis, the obtained results were found to be compatible with the earlier analysis carried out for the microflares through Reuven Ramety High Energy Solar Spectroscopic Imager (RHESSI), Solar Dynamics Observatory / Atmospheric Imaging Assembly (SDO/AIA) and NuSTAR observations. Here, we observed that EM decreases with increasing plasma temperature ( T ). We find that τ c ( T ) scale with plasma temperature ( T ) with an inverse gradient exhibits time delay characteristic of the cooling process of plasma. The correlation of E th and temperature ( T ) shows moderate anticorrelation. The present analysis demonstrates the multithermal plasma model and conduction cooling process during high temperature of microflares (similar to large flares) followed by radiative cooling in post-flare.
ISSN:0304-4289
0973-7111
DOI:10.1007/s12043-018-1697-8