About: Effect of turbulent density-fluctuations on wave-particle interactions and solar flare X-ray spectra

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Attributs	Valeurs
type	work Article
Is Part Of	http://hub.abes.fr/edp/periodical/aa/2013/volume_550/issue_2013/w
Subject	The Sun Sun: X-rays, gamma rays Sun: flares
Title	Effect of turbulent density-fluctuations on wave-particle interactions and solar flare X-ray spectra
Date	2013-01-01(xsd:dateTime)
has manifestation of work	http://hub.abes.fr/edp/periodical/aa/2013/volume_550/issue_2013/aa20462-12/m/web http://hub.abes.fr/edp/periodical/aa/2013/volume_550/issue_2013/aa20462-12/m/print
related by	http://hub.abes.fr/edp/periodical/aa/2013/volume_550/issue_2013/aa20462-12/authorship/2 http://hub.abes.fr/edp/periodical/aa/2013/volume_550/issue_2013/aa20462-12/authorship/3 http://hub.abes.fr/edp/periodical/aa/2013/volume_550/issue_2013/aa20462-12/authorship/1
Author	Kontar Eduard P Reid, H. A. S. Hannah, I. G.
Abstract	Aims. The aim of this paper is to demonstrate the effect of turbulent background density-fluctuations on flare-accelerated electron transport in the solar corona. Methods. Using the quasi-linear approximation, we numerically simulated the propagation of a beam of accelerated electrons from the solar corona to the chromosphere, including the self-consistent response of the inhomogeneous background plasma in the form of Langmuir waves. We calculated the X-ray spectrum from these simulations using the bremsstrahlung cross-section and fitted the footpoint spectrum using the collisional “thick-target” model, a standard approach adopted in observational studies. Results. We find that the interaction of the Langmuir waves with the background electron density gradient shifts the waves to a higher phase velocity where they then resonate with higher velocity electrons. The consequence is that some of the electrons are shifted to higher energies, producing more high-energy X-rays than expected if the density inhomogeneity is not considered. We find that the level of energy gain is strongly dependent on the initial electron beam density at higher energy and the magnitude of the density gradient in the background plasma. The most significant gains are for steep (soft) spectra that initially had few electrons at higher energies. If the X-ray spectrum of the simulated footpoint emission are fitted with the standard “thick-target” model (as is routinely done with RHESSI observations) some simulation scenarios produce more than an order-of-magnitude overestimate of the number of electrons >50 keV in the source coronal distribution.
article type	research-article
publisher identifier	aa20462-12
Date Copyrighted	2013-01-01(xsd:dateTime)
Rights	© ESO, 2013
Rights Holder	ESO
is part of this journal	Astronomy & Astrophysics
is primary topic of	http://hub.abes.fr/edp/periodical/aa/2013/volume_550/issue_2013/aa20462-12/w/record

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