Properties of solar energetic particle events inferred from their associated radio emission

Kouloumvakos, A.; Nindos, A.; Валтонен, Э.; Alissandrakis, C. E.; Malandraki, O.; Tsitsipis, P.; Kontogeorgos, A.; Moussas, X.; Hillaris, A.

doi:10.1051/0004-6361/201424397

Cited by 52 publications

(55 citation statements)

References 66 publications

(98 reference statements)

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“…Radio emissions have a rich diagnostic potential about the acceleration and propagation of solar energetic particles (Kouloumvakos et al 2015). Additionally, they provide important information on the location and temporal evolution of the particle release processes from the corona into the IP medium (Agueda et al 2014).…”

Section: Radio Datamentioning

confidence: 99%

Solar flares, coronal mass ejections and solar energetic particle event characteristics

Papaioannou

Sandberg

Anastasiadis

et al. 2016

J. Space Weather Space Clim.

126

129

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A new catalogue of 314 solar energetic particle (SEP) events extending over a large time span from 1984 to 2013 has been compiled. The properties as well as the associations of these SEP events with their parent solar sources have been thoroughly examined. The properties of the events include the proton peak integral flux and the fluence for energies above 10, 30, 60 and 100 MeV. The associated solar events were parametrized by solar flare (SF) and coronal mass ejection (CME) characteristics, as well as related radio emissions. In particular, for SFs: the soft X-ray (SXR) peak flux, the SXR fluence, the heliographic location, the rise time and the duration were exploited; for CMEs the plane-of-sky velocity as well as the angular width were utilized. For radio emissions, type III, II and IV radio bursts were identified. Furthermore, we utilized element abundances of Fe and O. We found evidence that most of the SEP events in our catalogue do not conform to a simple two-class paradigm, with the 73% of them exhibiting both type III and type II radio bursts, and that a continuum of event properties is present. Although, the so-called hybrid or mixed events are found to be present in our catalogue, it was not possible to attribute each SEP event to a mixed/hybrid sub-category. Moreover, it appears that the start of the type III burst most often precedes the maximum of the SF and thus falls within the impulsive phase of the associated SF. At the same time, type III bursts take place within %5.22 min, on average, in advance from the time of maximum of the derivative of the SXR flux (Neupert effect). We further performed a statistical analysis and a mapping of the logarithm of the proton peak flux at E > 10 MeV, on different pairs of the parent solar source characteristics. This revealed correlations in 3-D space and demonstrated that the gradual SEP events that stem from the central part of the visible solar disk constitute a significant radiation risk. The velocity of the associated CMEs, as well as the SXR peak flux and fluence, are all fairly significantly correlated to both the proton peak flux and the fluence of the SEP events in our catalogue. The strongest correlation to SEP characteristics is manifested by the CME velocity.

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Section: Radio Datamentioning

confidence: 99%

Solar flares, coronal mass ejections and solar energetic particle event characteristics

Papaioannou

Sandberg

Anastasiadis

et al. 2016

J. Space Weather Space Clim.

126

129

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“…Solar Type III bursts are produced by electron beams moving at speeds of order 10% of the speed of light, with radio frequency decreasing exponentially on a timescale of seconds; when these bursts occur at low frequencies, they indicate that energetic electrons (and likely protons as well) are escaping the solar corona on open magnetic field lines. Both of these classes of bursts are correlated with solar space weather events that impact Earth: coronal mass ejections and solar energetic particle (SEP) events (Kouloumvakos et al 2015). Analogous events, tracing bulk motion of plasma, may be detectable from nearby stars; and based on Sun-as-a-star data, such stellar radio bursts can be used to recover approximate dynamical properties of CMEs (Crosley et al 2017).…”

Section: Introductionmentioning

confidence: 99%

Ultra-wideband Detection of 22 Coherent Radio Bursts on M Dwarfs

Villadsen

Hallinan

2019

ApJ

106

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Coherent radio bursts detected from M dwarfs have some analogy with solar radio bursts, but reach orders of magnitude higher luminosities. These events trace particle acceleration, powered by magnetic reconnection, shock fronts (such as formed by coronal mass ejections, CMEs), and magnetospheric currents, in some cases offering the only window into these processes in stellar atmospheres. We conducted a 58-hour, ultra-wideband survey for coherent radio bursts on 5 active M dwarfs. We used the Karl G. Jansky Very Large Array (VLA) to observe simultaneously in three frequency bands covering a subset of 224-482 MHz and 1-6 GHz, achieving the widest fractional bandwidth to date for any observations of stellar radio bursts. We detected 22 bursts across 13 epochs, providing the first large sample of wideband dynamic spectra of stellar coherent radio bursts. The observed bursts have diverse morphology, with durations ranging from seconds to hours, but all share strong (40-100%) circular polarization. No events resemble solar Type II bursts (often associated with CMEs), but we cannot rule out the occurrence of radio-quiet stellar CMEs. The hours-long bursts are all polarized in the sense of the x-mode of the star's large-scale magnetic field, suggesting they are cyclotron maser emission from electrons accelerated in the large-scale field, analogous to auroral processes on ultracool dwarfs. The duty cycle of luminous coherent bursts peaks at 25% at 1-1.4 GHz, declining at lower and higher frequencies, indicating source regions in the low corona. At these frequencies, active M dwarfs should be the most common galactic transient source.

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“…Although both SEP solar particle release (SPR) times and EM onsets have been discussed at length in the past, comparison between electron release times and proton release times has been discussed only in a few papers [e.g., Cliver et al , ; Haggerty and Roelof , ; Kouloumvakos et al , ; Kahler et al , ; Posner , ]. In Posner []'s study, the author adopted the prevailing assumption of simultaneous release of electrons and protons, but he also pointed out that “release of protons before electrons (and vice versa) is possible (E. Roelof and D. Haggerty, personal communication, 2006)”.…”

Section: Introductionmentioning

confidence: 99%

“…They found that half of GLE events the relativistic proton injection preceded that of electrons; however, the low‐intensity GLEs tend to have a later time for the proton injection. Recently, Kouloumvakos et al [] compared the proton and electron release as inferred from velocity dispersion analysis (VDA) based on Wind/3DP and Energetic and Relativistic Nuclei and Electron instrument (ERNE) data and found a 7 min average delay of near‐relativistic electrons with respect to deka‐MeV protons. Haggerty and Roelof [] studied 19 electron beam events using Electron, Proton, and Alpha Monitor (EPAM) 38–315 keV data and found that for 11 of the 19 events the arrival of 50–100 MeV protons followed by electrons within ∼3 min.…”

Section: Introductionmentioning

confidence: 99%

Energy dependence of SEP electron and proton onset times

et al. 2016

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We study the large solar energetic particle (SEP) events that were detected by GOES in the >10 MeV energy channel during December 2006 to March 2014. We derive and compare solar particle release (SPR) times for the 0.25–10.4 MeV electrons and 10–100 MeV protons for the 28 SEP events. In the study, the electron SPR times are derived with the time‐shifting analysis (TSA) and the proton SPR times are derived using both the TSA and the velocity dispersion analysis (VDA). Electron anisotropies are computed to evaluate the amount of scattering for the events under study. Our main results include (1) near‐relativistic electrons and high‐energy protons are released at the same time within 8 min for most (16 of 23) SEP events. (2)There exists a good correlation between electron and proton acceleration, peak intensity, and intensity time profiles. (3) The TSA SPR times for 90.5 MeV and 57.4 MeV protons have maximum errors of 6 min and 10 min compared to the proton VDA release times, respectively, while the maximum error for 15.4 MeV protons can reach to 32 min. (4) For 7 low‐intensity events of the 23, large delays occurred for 6.5 MeV electrons and 90.5 MeV protons relative to 0.5 MeV electrons. Whether these delays are due to times needed for the evolving shock to be strengthened or due to particle transport effects remains unsolved.

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Properties of solar energetic particle events inferred from their associated radio emission

Cited by 52 publications

References 66 publications

Solar flares, coronal mass ejections and solar energetic particle event characteristics

Solar flares, coronal mass ejections and solar energetic particle event characteristics

Ultra-wideband Detection of 22 Coherent Radio Bursts on M Dwarfs

Energy dependence of SEP electron and proton onset times

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