Inference of Heating Properties From “Hot” Non-Flaring Plasmas in Active Region Cores. I. Single Nanoflares

Barnes, Will T.; Cargill, P. J.; Bradshaw, S. J.

doi:10.3847/0004-637x/829/1/31

Cited by 51 publications

(44 citation statements)

References 63 publications

(131 reference statements)

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“…Thus EBTEL is expected to provide a good approximation at least in the long gradual phase of the flare. Other effects, e.g., how the spatial and temporal changes of the cross section (Klimchuk 2001;Mikić et al 2013) and the plasma composition (Phillips 2004;Barnes et al 2016) affect the hydrodynamic evolution of a loop/thread should be evaluated in the future study.…”

Section: Discussionmentioning

confidence: 99%

Two-phase Heating in Flaring Loops

Zhu

Qiu

Longcope

2018

ApJ

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We analyze and model a C5.7 two-ribbon solar flare observed by SDO, Hinode and GOES on 2011 December 26. The flare is made of many loops formed and heated successively over one and half hours, and their foot-points are brightened in the UV 1600Å before enhanced soft X-ray and EUV missions are observed in flare loops. Assuming that anchored at each brightened UV pixel is a half flaring loop, we identify more than 6,700 half flaring loops, and infer the heating rate of each loop from the UV light curve at the foot-point. In each half loop, the heating rate consists of two phases, an intense impulsive heating followed by a low-rate heating persistent for more than 20 minutes. Using these heating rates, we simulate the evolution of their coronal temperatures and densities with the model of "enthalpy-based thermal evolution of loops" (EBTEL). In the model, suppression of thermal conduction is also considered. This model successfully reproduces total soft X-ray and EUV light curves observed in fifteen pass-bands by four instruments GOES, AIA, XRT, and EVE. In this flare, a total energy of 4.9×10 30 ergs is required to heat the corona, around 40% of this energy is in the slow-heating phase. About two fifth of the total energy used to heat the corona is radiated by the coronal plasmas, and the other three fifth transported to the lower atmosphere by thermal conduction.

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Section: Discussionmentioning

confidence: 99%

Two-phase Heating in Flaring Loops

Zhu

Qiu

Longcope

2018

ApJ

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“…There is ample evidence for acceleration processes in the solar corona that result in nonthermal particle distributions. These include the radiative signatures and direct particle detections in large eruptive events that result in flares and coronal mass ejections (CMEs) (Zharkova et al 2011;Vilmer 2012;Aschwanden 2012;Miller et al 1997;Kontar et al 2011;Holman et al 2011;Aschwanden et al 2017). The underlying driver for such particle acceleration events is generally understood to be the excess energy stored in stressed magnetic fields that is released via the process of magnetic reconnection.…”

Section: Introductionmentioning

confidence: 99%

“…While this broad picture has been accepted for a while, it is only recently that observations have started to reveal some details (Kontar et al 2017) and simulations have started to establish the details of particle acceleration in reconnection regions (e.g., (Vlahos et al 2016;Arzner & Vlahos 2004;Dahlin et al 2015) and references therein). On the other hand, the possibility of small, ubiquitous reconnection events accelerating electrons and giving rise to the so-called nanoflares (Parker 1988) has gained considerable momentum as a candidate for coronal heating (e.g., (Klimchuk 2015;Barnes et al 2016) and references therein).Recent simulations have demonstrated the spontaneous development of current sheets with a high filling factor, even away from magnetic nulls ((Kumar et al 2015;Kumar & Bhattacharyya 2016)); these current sheets can serve as potential E-mail: tomin.james@students.iiserpune.ac.in sites for small electron acceleration events. However, since these nanoflares are very small, its very difficult to observe them directly (e.g.…”

Section: Introductionmentioning

confidence: 99%

Small electron acceleration episodes in the solar corona

James

Subramanian

Kontar

2017

Monthly Notices of the Royal Astronomical Society

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We study the energetics of nonthermal electrons produced in small acceleration episodes in the solar corona. We carried out an extensive survey spanning 2004-2015 and shortlisted 6 impulsive electron events detected at 1 AU that were not associated with large solar flares(GOES soft x-ray class > C1) or with coronal mass ejections. Each of these events had weak, but detectable hard Xray (HXR) emission near the west limb, and were associated with interplanetary type III bursts. In some respects, these events seem like weak counterparts of "cold/tenuous" flares. The energy carried by the HXR producing electron population was ≈ 10 23 -10 25 erg, while that in the corresponding population detected at 1 AU was ≈ 10 24 -10 25 erg. The number of electrons that escape the coronal acceleration site and reach 1 AU constitute 6 % to 148 % of those that precipitate downwards to produce thick target HXR emission.

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“…When considering the role of nanoflares in the production of hot plasma in AR cores, it is important to take NEI into account (Bradshaw & Cargill 2006;Reale & Orlando 2008;Barnes et al 2016). In a steady heating scenario, the ionization state is an adequate measure of the electron plasma temperature.…”

Section: Non-equilibrium Ionizationmentioning

confidence: 99%

Inference of Heating Properties From “Hot” Non-Flaring Plasmas in Active Region Cores. Ii. Nanoflare Trains

Barnes

Cargill

Bradshaw

2016

ApJ

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Despite its prediction over two decades ago, the detection of faint, high-temperature ("hot") emission due to nanoflare heating in non-flaring active region cores has proved challenging. Using an efficient two-fluid hydrodynamic model, this paper investigates the properties of the emission expected from repeating nanoflares (a nanoflare train) of varying frequency as well as the separate heating of electrons and ions. If the emission measure distribution (EM(T)) peaks at T = T m , we find that EM(T m ) is independent of details of the nanoflare train, and EM(T) above and below T m reflects different aspects of the heating. Below T m , the main influence is the relationship of the waiting time between successive nanoflares to the nanoflare energy. Above T m , power-law nanoflare distributions lead to an extensive plasma population not present in a mono-energetic train. Furthermore, in some cases, characteristic features are present in EM(T). Such details may be detectable given adequate spectral resolution and a good knowledge of the relevant atomic physics. In the absence of such resolution we propose some metrics that can be used to infer the presence of "hot" plasma.

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Inference of Heating Properties From “Hot” Non-Flaring Plasmas in Active Region Cores. I. Single Nanoflares

Cited by 51 publications

References 63 publications

Two-phase Heating in Flaring Loops

Two-phase Heating in Flaring Loops

Small electron acceleration episodes in the solar corona

Inference of Heating Properties From “Hot” Non-Flaring Plasmas in Active Region Cores. Ii. Nanoflare Trains

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