Abstract
Abstract We present numerical modeling of particle acceleration at coronal shocks propagating through a streamer-like magnetic field by solving the Parker transport equation with spatial diffusion both along and across the magnetic field. We show that the location on the shock where the high-energy particle intensity is the largest, depends on the energy of the particles and on time. The acceleration of particles to more than 100 MeV mainly occurs in the shock-streamer interaction region, due to perpendicular shock geometry and the trapping effect of closed magnetic fields. A comparison of the particle spectra to that in a radial magnetic field shows that the intensity at 100 MeV (200 MeV) is enhanced by more than one order (two orders) of magnitude. This indicates that the streamer-like magnetic field can be an important factor in producing large solar energetic particle events. We also show that the energy spectrum integrated over the simulation domain consists of two different power laws. Further analysis suggests that it may be a mixture of two distinct populations accelerated in the streamer and open field regions, where the acceleration rate differs substantially. Our calculations also show that the particle spectra are affected considerably by a number of parameters, such as the streamer tilt angle, particle spatial diffusion coefficient, and shock compression ratio. While the low-energy spectra agree well with standard diffusive shock acceleration theory, the break energy ranges from ∼1 MeV to ∼90 MeV and the high-energy spectra can extend to ∼1 GeV with a slope of ∼2–3.
Highlights
Charged particles can be accelerated to energies beyond a few GeV near the Sun during large solar eruptions such as flares and coronal mass ejections (CMEs; see reviews, Reames 1999; Desai & Giacalone 2016)
While the earlier study (Kong et al 2017) has shown that the shockstreamer interaction region can be a vital acceleration site for high-energy solar energetic particle (SEP), the current simulation reveals a more complicated energetic particle distribution when the shock is propagating at a tilted angle compared to the streamer
We have further investigated the effect of largescale coronal magnetic configuration on particle acceleration at coronal shocks
Summary
Charged particles can be accelerated to energies beyond a few GeV near the Sun during large solar eruptions such as flares and coronal mass ejections (CMEs; see reviews, Reames 1999; Desai & Giacalone 2016). Kong et al (2017) presented a numerical model to investigate particle acceleration at CME-driven shocks close to the Sun, by considering a coronal shock with a kinematic description propagating through a streamer-like magnetic field. We further investigate the effect of large-scale streamerlike magnetic configuration on particle acceleration at coronal shocks when the CME shock originates outside of the streamer and propagates through the streamer from the flank. To study the effect of various parameters on particle acceleration, such as the streamer tilt angle (Θtilt), particle spatial diffusion coefficient (by varying κP0/κ0 and κ⊥/κP), and shock compression ratio (X), we do a parameter study by including eight simulations in addition to the reference run.
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