What Dominates the Coronal Emission Spectrum During the Cycle of Impulsive Heating and Cooling?

Bradshaw, S. J.; Klimchuk, J. A.

doi:10.1088/0067-0049/194/2/26

Cited by 101 publications

(110 citation statements)

References 36 publications

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“…This will not be the case for the extremely hot and tenuous plasma that is present shortly after a nanoflare occurs (Bradshaw & Cargill 2006;Reale & Orlando 2008). Since the emission from highly ionized species is diminished in this situation, the high-temperature peaks of the response functions of the 131 channel and, to a lesser extent, the 94 channel predict stronger emission than can actually be expected (Bradshaw & Klimchuk 2011). …”

Section: Data and Modelingmentioning

confidence: 99%

“…It is important to know whether the count rates observed in the AR core are also consistent with nanoflare storm heating. Bradshaw & Klimchuk (2011) predict count rates in several AIA channels for the loop apex of 14 different nanoflare models computed with the 1D HYDRAD code (Bradshaw & Cargill 2010, and references therein), taking full account of nonequilibrium ionization. The 195/335 ratio ranges between 13 and 446 and has a median value of 46.…”

Section: Location 3: Diffuse Emissionmentioning

confidence: 99%

“…In comparison, the average 195 and 335 count rates in a 30 × 20 pixel area in the core of this observed AR have a ratio of 11. Bradshaw & Klimchuk (2011) did not determine count rates for the 171 channel. The overall magnitudes of the intensities observed in this AR core are consistent with the models.…”

Section: Location 3: Diffuse Emissionmentioning

confidence: 99%

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PATTERNS OF NANOFLARE STORM HEATING EXHIBITED BY AN ACTIVE REGION OBSERVED WITHSOLAR DYNAMICS OBSERVATORY/ATMOSPHERIC IMAGING ASSEMBLY

Viall

Klimchuk

2011

ApJ

110

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It is largely agreed that many coronal loops-those observed at a temperature of about 1 MK-are bundles of unresolved strands that are heated by storms of impulsive nanoflares. The nature of coronal heating in hotter loops and in the very important but largely ignored diffuse component of active regions is much less clear. Are these regions also heated impulsively, or is the heating quasi-steady? The spectacular new data from the Atmospheric Imaging Assembly (AIA) telescopes on the Solar Dynamics Observatory offer an excellent opportunity to address this question. We analyze the light curves of coronal loops and the diffuse corona in six different AIA channels and compare them with the predicted light curves from theoretical models. Light curves in the different AIA channels reach their peak intensities with predictable orderings as a function the nanoflare storm properties. We show that while some sets of light curves exhibit clear evidence of cooling after nanoflare storms, other cases are less straightforward to interpret. Complications arise because of line-of-sight integration through many different structures, the broadband nature of the AIA channels, and because physical properties can change substantially depending on the magnitude of the energy release. Nevertheless, the light curves exhibit predictable and understandable patterns consistent with impulsive nanoflare heating.

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Section: Data and Modelingmentioning

confidence: 99%

Section: Location 3: Diffuse Emissionmentioning

confidence: 99%

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PATTERNS OF NANOFLARE STORM HEATING EXHIBITED BY AN ACTIVE REGION OBSERVED WITHSOLAR DYNAMICS OBSERVATORY/ATMOSPHERIC IMAGING ASSEMBLY

Viall

Klimchuk

2011

ApJ

110

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“…We used the same response functions as Bradshaw and Klimchuk (2011); these functions are a product of the plate scale, effective area, and gain of the AIA instrument.…”

Section: Forward Modellingmentioning

confidence: 99%

Forward Modelling of a Brightening Observed by AIA

et al. 2015

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A comprehensive understanding of the different transient events is necessary for any eventual solution of the coronal heating problem. We present a cold loop whose heating caused a short-lived small-scale brightening that was observed by AIA. The loop was simulated using an adaptive hydrodynamic radiation code that considers the ions to be in a state of non-equilibrium. Forward modelling was used to create synthetic AIA intensity plots, which were tested against the observational data to confirm the simulated properties of the event. The hydrodynamic properties of the loop were determined. We found that the energy released by the heating event is within the canonical energy range of a nanoflare.

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“…However, in the case of hot coronal loops, there is observational support for both steady heating (Antiochos et al 2003;Warren et al 2008Warren et al , 2010Winebarger et al 2008Winebarger et al , 2011) and impulsive heating (Tripathi et al 2010b(Tripathi et al , 2011Bradshaw & Klimchuk 2011;Viall et al 2012). Because of the unresolved nature of hot coronal loops (Tripathi et al 2009) it is not possible to isolate a single loop and study its characteristics.…”

Section: Introductionmentioning

confidence: 99%

Doppler shift of hot coronal lines in a moss area of an active region

Dadashi

Teriaca

Tripathi

et al. 2012

A&A

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The moss is the area at the footpoint of the hot (3 to 5 MK) loops forming the core of the active region where emission is believed to result from the heat flux conducted down to the transition region from the hot loops. Studying the variation of Doppler shift as a function of line formation temperatures over the moss area can give clues on the heating mechanism in the hot loops in the core of the active regions. We investigate the absolute Doppler shift of lines formed at temperatures between 1 MK and 2 MK in a moss area within active region NOAA 11243 using a novel technique that allows determining the absolute Doppler shift of EUV lines by combining observations from the SUMER and EIS spectrometers. The inner (brighter and denser) part of the moss area shows roughly constant blue shift (upward motions) of 5 km s −1 in the temperature range of 1 MK to 1.6 MK. For hotter lines the blue shift decreases and reaches 1 km s −1 for Fe xv 284 Å (∼2 MK). The measurements are discussed in relation to models of the heating of hot loops.The results for the hot coronal lines seem to support the quasi-steady heating models for nonsymmetric hot loops in the core of active regions.

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What Dominates the Coronal Emission Spectrum During the Cycle of Impulsive Heating and Cooling?

Cited by 101 publications

References 36 publications

PATTERNS OF NANOFLARE STORM HEATING EXHIBITED BY AN ACTIVE REGION OBSERVED WITHSOLAR DYNAMICS OBSERVATORY/ATMOSPHERIC IMAGING ASSEMBLY

PATTERNS OF NANOFLARE STORM HEATING EXHIBITED BY AN ACTIVE REGION OBSERVED WITHSOLAR DYNAMICS OBSERVATORY/ATMOSPHERIC IMAGING ASSEMBLY

Forward Modelling of a Brightening Observed by AIA

Doppler shift of hot coronal lines in a moss area of an active region

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