The Acceleration of High-energy Protons at Coronal Shocks: The Effect of Large-scale Streamer-like Magnetic Field Structures

Kong, Xiangliang; Guo, Fan; Giacalone, J.; Li, Hui; Chen, Yao

doi:10.3847/1538-4357/aa97d7

Cited by 44 publications

(52 citation statements)

References 82 publications

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“…Such shocks can efficiently accelerate both the interacting protons producing the pion decay γ-ray emissions at the Sun and the interplanetary protons responsible for the prompt component of the GLE at the Earth. Several relevant acceleration models were considered by Kocharov et al (2011Kocharov et al ( , 2012, Kong et al (2017), and Kouloumvakos et al (2020).…”

Section: Discussionmentioning

confidence: 99%

Multiple Sources of Solar High-energy Protons

Kocharov

Omodei

Mishev

et al. 2021

ApJ

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During the 24th solar cycle, the Fermi Large Area Telescope (LAT) has observed a total of 27 solar flares possessing delayed γ-ray emission, including the exceptionally well-observed flare and coronal mass ejection (CME) on 2017 September 10. Based on the Fermi/LAT data, we plot, for the first time, maps of possible sources of the delayed >100 MeV γ-ray emission of the 2017 September 10 event. The long-lasting γ-ray emission is localized under the CME core. The γ-ray spectrum exhibits intermittent changes in time, implying that more than one source of high-energy protons was formed during the flare-CME eruption. We find a good statistical correlation between the γ-ray fluences of the Fermi/LAT-observed delayed events and the products of corresponding CME speed and the square root of the soft X-ray flare magnitude. Data support the idea that both flares and CMEs jointly contribute to the production of subrelativistic and relativistic protons near the Sun.

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Section: Discussionmentioning

confidence: 99%

Multiple Sources of Solar High-energy Protons

Kocharov

Omodei

Mishev

et al. 2021

ApJ

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“…The resulting correlations are not statistically significant, and an apparent relation is difficult to establish from Figure 9. Recent studies have shown that for a realistic coronal structure the seed particles gain energy gradually by interacting with a rapidly varying shock geometry (e.g., Sandroos & Vainio 2009;Kong et al 2017). A proper evaluation of the role of shock geometry on the acceleration process requires a more refined analysis that folds in time dependency.…”

Section: Summary and Discussionmentioning

confidence: 99%

Connecting the Properties of Coronal Shock Waves with Those of Solar Energetic Particles

Kouloumvakos

Rouillard

et al. 2019

ApJ

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We develop and exploit a new catalog of coronal pressure waves modeled in 3D to study the potential role of these waves in accelerating solar energetic particles (SEPs) measured in situ. Our sample comprises modeled shocks and SEP events detected during solar cycle 24 observed over a broad range of longitudes. From the 3D reconstruction of shock waves using coronagraphic observations we derived the 3D velocity along the entire front as a function of time. Combining new reconstruction techniques with global models of the solar corona, we derive the 3D distribution of basic shock parameters such as Mach numbers, compression ratios, and shock geometry. We then model in a time-dependent manner how the shock wave connects magnetically with spacecraft making in situ measurements of SEPs. This allows us to compare modeled shock parameters deduced at the magnetically wellconnected regions, with different key parameters of SEPs such as their maximum intensity. This approach accounts for projection effects associated with remote-sensing observations and constitutes the most extensive study to date of shock waves in the corona and their relation to SEPs. We find a high correlation between the maximum flux of SEPs and the strength of coronal shock waves quantified, for instance, by the Mach number. We discuss the implications of that work for understanding particle acceleration in the corona.

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“…They demonstrated that the familiar planar-shock results can be significantly altered as a consequence of large-scale, meandering magnetic lines of force. Because the perpendicular diffusion coefficient κ ⊥ is generally much smaller than the parallel diffusion coefficient κ , energetic charged particles are trapped and preferentially accelerated along the shock front in regions where the connection points of magnetic field lines intersecting the shock surface converge, and thus create "hot spots" of accelerated particles (see also Kong et al, 2017;Kong et al, 2019a). For regions where the connection points are separated from each other, the acceleration to high energies will be suppressed.…”

Section: Implications To Variability Of Energetic Particlesmentioning

confidence: 99%

Shock Propagation and Associated Particle Acceleration in the Presence of Ambient Solar-Wind Turbulence

Guo

Giacalone

Zhao

2021

Front. Astron. Space Sci.

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The topic of this review paper is on the influence of solar wind turbulence on shock propagation and its consequence on the acceleration and transport of energetic particles at shocks. As the interplanetary shocks sweep through the turbulent solar wind, the shock surfaces fluctuate and ripple in a range of different scales. We discuss particle acceleration at rippled shocks in the presence of ambient solar-wind turbulence. This strongly affects particle acceleration and transport of energetic particles (both ions and electrons) at shock fronts. In particular, we point out that the effects of upstream turbulence is critical for understanding the variability of energetic particles at shocks. Moreover, the presence of pre-existing upstream turbulence significantly enhances the trapping near the shock of low-energy charged particles, including those near the thermal energy of the incident plasma, even when the shock propagates normal to the average magnetic field. Pre-existing turbulence, always present in space plasmas, provides a means for the efficient acceleration of low-energy particles and overcoming the well known injection problem at shocks.

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The Acceleration of High-energy Protons at Coronal Shocks: The Effect of Large-scale Streamer-like Magnetic Field Structures

Cited by 44 publications

References 82 publications

Multiple Sources of Solar High-energy Protons

Multiple Sources of Solar High-energy Protons

Connecting the Properties of Coronal Shock Waves with Those of Solar Energetic Particles

Shock Propagation and Associated Particle Acceleration in the Presence of Ambient Solar-Wind Turbulence

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