Quasi-periodic Pulsations in a Solar Microflare

Nakariakov, V. M.; Anfinogentov, Sergey; Storozhenko, A. A.; Kurochkin, E. A.; Bogod, V. M.; Sharykin, I. N.; Kaltman, T. I.

doi:10.3847/1538-4357/aabfb9

Cited by 44 publications

(37 citation statements)

References 50 publications

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“…Likewise, signatures of FSMs were also found in the fine structures in a number of flare-associated radio bursts as measured by, say, the Chinese Solar Broadband Radio Spectrometer (Yu et al 2013(Yu et al , 2016, the Assembly of Metric-band Aperture Telescope and Real-time Analysis System (Kaneda et al 2018), and the LOw Frequency ARray (Kolotkov et al 2018). Furthermore, a recent multi-wavelength study by Nakariakov et al (2018) suggested the existence of FSMs in loops associated with microflares. In extreme ultraviolet (EUV), Su et al (2012) identified FSMs using imaging observations in the 171Å channel of the Atmospheric Imaging Assembly (AIA) aboard the Solar Dynamics Observatory (SDO).…”

Section: Introductionmentioning

confidence: 99%

Synthetic Emissions of the Fe xxi 1354 Å Line from Flare Loops Experiencing Fundamental Fast Sausage Oscillations

Shi

Huang

et al. 2019

ApJ

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Inspired by recent IRIS observations, we forward model the response of the Fe XXI 1354Å line to fundamental, standing, linear fast sausage modes (FSMs) in flare loops. Starting with the fluid parameters for an FSM in a straight tube with equilibrium parameters largely compatible with the IRIS measurements, we synthesize the line profiles by incorporating the non-Equilibrium Ionization (NEI) effect in the computation of the contribution function. We find that both the intensity and Doppler shift oscillate at the wave period (P ). The phase difference between the two differs from the expected value (90 • ) only slightly because NEI plays only a marginal role in determining the ionic fraction of Fe XXI in the examined dense loop. The Doppler width modulations, however, posses an asymmetry in the first and second halves of a wave period, leading to a secondary periodicity at P/2 in addition to the primary one at P . This behavior results from the competition between the broadening due to bulk flow and that due to temperature variations, with the latter being stronger but not overwhelmingly so. These expected signatures, with the exception of the Doppler width, are largely consistent with the IRIS measurements, thereby corroborating the reported detection of a fundamental FSM. The forward modeled signatures are useful for identifying fundamental FSMs in flare loops from measurements of the Fe XXI 1354Å line with instruments similar to IRIS, even though a much higher cadence is required for the expected behavior in the Doppler widths to be detected.

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Section: Introductionmentioning

confidence: 99%

Synthetic Emissions of the Fe xxi 1354 Å Line from Flare Loops Experiencing Fundamental Fast Sausage Oscillations

Shi

Huang

et al. 2019

ApJ

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“…The black arrow indicates the time of corresponding radio fine structure spectrum observed by SBRS at 1100-1900 MHz band, shown on the second panel. The four bottom panels are SDO AIA 171 Å images after running differentiation [Nakajima, 1994]. We can expect that the weak radio bursts observed with the high-sensitivity low-interference telescope will help us to understand physical characteristics of small-scale eruptions and nano-flares, and will further expand our understanding of solar radio emission and solar magnetic field.…”

Section: Resultsmentioning

confidence: 98%

Fine structure events in microwave emission during solar minimum

Чэнмин¹,

Tan

Биолинь³

et al. 2019

Solnechno-Zemnaya Fizika

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The solar minimum is a period with a relatively smaller number of sunspots and solar eruptions, and has been less studied before. Since the radio signal rapidly responds to the change of solar plasma and magnetic field, we perform a comprehensive analysis of high resolution spectrum data from SBRS and MUSER: 1) a search for solar radio bursts of different kinds in recent solar minima (2007–2009 and 2016–2018); 2) an analysis of several typical radio burst events, negative and positive drifting bursts, for example the November 22, 2015 and August 29, 2016 events; superfine spectral structure events with mini-flares and even without sunspots, for example the March 28, 2008 and July 04, 2017 events. These results show that there were many radio bursts with a fine structure during solar minima. These events occurred not only in powerful flares, but also in faint flares (class C and B by GOES) or even without flares, but in regions related to weak brightenings or ejecta. We assume that the weak solar radio bursts observed by telescopes with high sensitivity and low interference will help us to understand the basic physical characteristics of small-scale solar eruptions.

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“…The high temporal resolution traditionally available in the radio band seems to be most suitable for the detection of these boomerangshaped fast magnetoacoustic wave trains in observations. In particular, signatures of quasi-periodic fast propagating wave trains in solar radio bursts were detected by Mészárosová et al (2009) with the characteristic oscillation period about 71 s; Mészárosová et al (2011) with multiple periods about 0.5 s, 2 s, and 81 s; Goddard et al (2016) with a period about 1.8 min; and Kumar et al (2017) with periods ranging from 70 s to 140 s. More recently, Nakariakov et al (2018) observed quasi-periodic pulsations in a solar microflare with periods about 1.4 s in the radio emission intensity and 0.7 s in the polarisation signal, which were interpreted in terms of fast sausage oscillations of the flaring loop. Kolotkov et al (2018) associated a 3-s quasi-periodic striation observed in the dynamic spectrum of a type III radio burst with the modulation of the local plasma density by a propagating fast wave train.…”

Section: Observational Illustration and Prospects For Coronal Seismologymentioning

confidence: 98%

Fast magnetoacoustic wave trains: from tadpoles to boomerangs

Kolotkov

Nakariakov

Moss

et al. 2021

Monthly Notices of the Royal Astronomical Society

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Rapidly propagating fast magnetoacoustic wave trains guided by field-aligned plasma non-uniformities are confidently observed in the Sun’s corona. Observations at large heights suggest that fast wave trains can travel long distances from the excitation locations. We study characteristic time signatures of fully developed, dispersive fast magnetoacoustic wave trains in field-aligned zero-β plasma slabs in the linear regime. Fast wave trains are excited by a spatially localised impulsive driver and propagate along the waveguide as prescribed by the waveguide-caused dispersion. In slabs with steeper transverse density profiles, developed wave trains are shown to consist of three distinct phases: a long-period quasi-periodic phase with the oscillation period shortening with time, a multi-periodic (peloton) phase in which distinctly different periods co-exist, and a short-lived periodic Airy phase. The appearance of these phases is attributed to a non-monotonic dependence of the fast wave group speed on the parallel wavenumber due to the waveguide dispersion, and is shown to be different for axisymmetric (sausage) and non-axisymmetric (kink) modes. In wavelet analysis, this corresponds to the transition from the previously known tadpole shape to a new boomerang shape of the wave train spectrum, with two well-pronounced arms at shorter and longer periods. We describe a specific previously published radio observation of a coronal fast wave train, highly suggestive of a change of the wavelet spectrum from a tadpole to a boomerang, broadly consistent with our modelling. The applicability of these boomerang-shaped fast wave trains for probing the transverse structuring of the waveguiding coronal plasma is discussed.

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Quasi-periodic Pulsations in a Solar Microflare

Cited by 44 publications

References 50 publications

Synthetic Emissions of the Fe xxi 1354 Å Line from Flare Loops Experiencing Fundamental Fast Sausage Oscillations

Synthetic Emissions of the Fe xxi 1354 Å Line from Flare Loops Experiencing Fundamental Fast Sausage Oscillations

Fine structure events in microwave emission during solar minimum

Fast magnetoacoustic wave trains: from tadpoles to boomerangs

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