Modeling of Gyrosynchrotron Radio Emission Pulsations Produced by Magnetohydrodynamic Loop Oscillations in Solar Flares

Mossessian, George; Fleishman, G. D.

doi:10.1088/0004-637x/748/2/140

Cited by 28 publications

(49 citation statements)

References 37 publications

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“…The loop lengths are taken from the EUV image (Figure 4). To calculate periods we used formulaes (9 -12) from Mossessian and Fleishman (2012). It is seen that the main observed period of 10 seconds can be excited in the small loop as sausage, kink, and torsional modes.…”

Section: The Qpp Modulationmentioning

confidence: 99%

“…Aschwanden, 1987;Grechnev, White, and Kundu, 2003). A quantitative study of the observable MW signatures of the MHD oscillation modes in the coronal loops was performed by Mossessian and Fleishman (2012). On the other hand the efficiency of particle acceleration mechanisms may strongly depend on changes of plasma parameters in acceleration sites, and the X-ray and microwave emission can therefore clearly respond to relatively weak disturbances associated with the MHD ones (e.g.…”

Section: Introductionmentioning

confidence: 99%

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Sources of Quasi-periodic Pulses in the Flare of 18 August 2012

et al. 2016

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We analyzed spatial and spectral characteristics of quasi-periodic pulses (QPP) for the 18 August 2012 limb flare, using new data from a complex of spectral and imaging instruments developed by the Siberian Solar Radio Telescope team and the Wind/Konus gamma-ray spectrometer. A sequence of broadband pulses with periods of approximately ten seconds were observed in Xrays at energies between 25 keV and 300 keV, and in microwaves at frequencies from a few GHz up to 34 GHz during an interval of one minute. The QPP Xray source was located slightly above the limb where the south legs of large and small EUV loop systems were close to each other. Before the QPPs the soft X-ray emission and the Ramaty High Energy Solar Spectroscopic Imager signal from the energy channels below 25 keV were gradually arising for several minutes at the same location. It was found that each X-ray pulse showed the soft-hard-soft behavior. The 17 and 34 GHz microwave source were at footpoints of the small loop system and the source emitting in the 4.2 -7.4 GHz band in the large one. The QPPs were probably generated by modulation of acceleration processes in the energy release site. Analyzing radio spectra we determined the plasma parameters in the radio sources. The microwave pulses could be explained by relatively weak variations of the spectrum hardness of emitting electrons.

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Section: The Qpp Modulationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Sources of Quasi-periodic Pulses in the Flare of 18 August 2012

et al. 2016

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“…Observational evidence of the sausage mode of a single flare loop has mostly come from radio instruments: the Nobeyama Radioheliograph (Stepanov 2004;Melnikov et al 2005;Reznikova et al 2007;Inglis et al 2008) and the Owens Valley Solar Array (Mossessian & Fleishman 2012). Microwave emission from solar flares detected by these instruments is mainly generated by gyrosynchrotron (GS) radiation of trapped nonthermal electrons.…”

Section: Introductionmentioning

confidence: 99%

“…For many years, phase relations between modulation of the low-( f < f peak ) and high-( f > f peak ) frequency radiation were considered to be an important criterion of mode identification. Previous theoretical studies of this process predicted a phase difference of π between the oscillation in the optically thin and optically thick regime for negligible Razin suppression, as well as an in-phase behavior of low-and high-frequency radiation for strong Razin suppression (e.g., see Kopylova et al 2002;Reznikova et al 2007;Mossessian & Fleishman 2012). However, these studies were made without spatial resolution: models assumed that the magnetic field and density oscillate in phase within the entire source.…”

Section: Introductionmentioning

confidence: 99%

“…However, when such measurements are available, they can be used to analyze the quasi-periodic pulsations of microwave emission as well. Thus, modeling the sausage wave without spatial resolution, Mossessian & Fleishman (2012) predicted that the high-(low-) frequency polarization is in phase with the high-(low-) frequency intensity and, therefore, the oscillating components at low ( f < f peak ) frequencies are out of phase by the amount of π relative to the high ( f > f peak ) frequencies.…”

Section: Introductionmentioning

confidence: 99%

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Perturbations of gyrosynchrotron emission polarization from solar flares by sausage modes: forward modeling

Reznikova

Doorsselaere

Kuznetsov

2015

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We examined the polarization of the microwave flaring emission and its modulation by the fast sausage standing wave using a linear 3D magnetohydrodynamic model of a plasma cylinder. We analyzed the effects of the line-of-sight angle on the perturbations of the gyrosynchrotron intensity for two models: a base model with strong Razin suppression and a low-density model in which the Razin effect was negligible. The circular polarization (Stokes V) oscillation is in phase with the intensity oscillation, and the polarization degree (Stokes V/I) oscillates in phase with the magnetic field at the examined frequencies in both models. The two quantities experience a periodical reversal of their signs with a period equal to half of the sausage wave period when seen at a 90 • viewing angle, in this case, their modulation depth reaches 100%.

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