2016
DOI: 10.1002/asna.201612427
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Hybrid simulations of chromospheric HXR flare sources

Abstract: Recent measurements of vertical extents and positions of the chromospheric hard X-ray (HXR) flare sources based on Ramaty High-Energy Spectroscopic Imager (RHESSI) observations show a significant inconsistency with the theoretical predictions based on the standard collisional thick target model (CTTM). Using a hybrid flare code Flarix, we model simultaneously and self-consistently the propagation, scattering and energy losses of electron beams with power-law energy spectra and various initial pitch-angle distr… Show more

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Cited by 4 publications
(4 citation statements)
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“…Similar behavior is seen in the evolution of heating due to electron beams in the Flarix code, as shown in e.g. Figure 2 of Moravec et al (2016). As evaporation drives the flow of plasma into the corona, the mean stopping depth is reduced and the energy deposition in the low corona begins to increase.…”
Section: Electron Beamssupporting
confidence: 68%
“…Similar behavior is seen in the evolution of heating due to electron beams in the Flarix code, as shown in e.g. Figure 2 of Moravec et al (2016). As evaporation drives the flow of plasma into the corona, the mean stopping depth is reduced and the energy deposition in the low corona begins to increase.…”
Section: Electron Beamssupporting
confidence: 68%
“…The original idea was based on an assumption that in the strong flares, the electron beams penetrate all the way down into the photosphere, where they by collisions heat the photospheric plasma, which then radiates thermally. Recent simulations (such as by Moravec et al, 2016) do not support this idea, because it seems that most of the energy in beams is deposited already at chromospheric levels and only a small fraction may propagate further down. Fletcher and Hudson (2008) suggested an alternative model in which the energy is transported from the reconnection site to the very deep layers of solar atmosphere by Alvén-wave pulses, which would provide an environment for the electrons in the lower atmosphere to be efficiently accelerated to high energies.…”
Section: White-light Flares On the Sunmentioning
confidence: 97%
“…Recently, this method has also been employed in studies of the warm-target model (Jeffrey et al 2014;Kontar et al 2015) and coupled hydrodynamic simulations of solar flares (e.g. Moravec et al 2016).…”
Section: Stochastic Simulation Schemementioning
confidence: 99%