THE CONTRIBUTION OF MICROBUNCHING INSTABILITY TO SOLAR FLARE EMISSION IN THE GHz TO THz RANGE OF FREQUENCIES

Klopf, J. Michael; Kaufmann, P.; Raulin, J. P.; Szpigel, S.

doi:10.1088/0004-637x/791/1/31

Cited by 8 publications

(1 citation statement)

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“…More recent observations at frequencies above 100 GHz indicated the presence of a new rising-with-frequency component (Kaufmann 2012). Although a large number of models is discussed in connection with this mysterious component, the exact mechanism of the emission remains unclear (Fleishman & Kontar 2010;Krucker et al 2013;Klopf et al 2014;Zaitsev et al 2014).…”

Section: Introductionmentioning

confidence: 99%

Narrowband Gyrosynchrotron Bursts: Probing Electron Acceleration in Solar Flares

Fleishman

Nita

Kontar

et al. 2016

ApJ

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Recently, in a few case studies we demonstrated that gyrosynchrotron microwave emission can be detected directly from the acceleration region when the trapped electron component is insignificant. For the statistical study reported here, we have identified events with steep (narrowband) microwave spectra that do not show a significant trapped component and, at the same time, show evidence of source uniformity, which simplifies the data analysis greatly. Initially, we identified a subset of more than 20 radio bursts with such narrow spectra, having low-and highfrequency spectral indices larger than three in absolute value. A steep low-frequency spectrum implies that the emission is nonthermal (for optically thick thermal emission, the spectral index cannot be steeper than two), and the source is reasonably dense and uniform. A steep high-frequency spectrum implies that no significant electron trapping occurs, otherwise a progressive spectral flattening would be observed. Roughly half of these radio bursts have RHESSI data, which allow for detailed, joint diagnostics of the source parameters and evolution. Based on an analysis of radio-to-X-ray spatial relationships, timing, and spectral fits, we conclude that the microwave emission in these narrowband bursts originates directly from the acceleration regions, which have a relatively strong magnetic field, high density, and low temperature. In contrast, the thermal X-ray emission comes from a distinct loop with a smaller magnetic field, lower density, but higher temperature. Therefore, these flares likely occurred due to interaction between two (or more) magnetic loops.

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Section: Introductionmentioning

confidence: 99%