Particle Acceleration at Coronal Shocks: the Effect of Large-scale Streamer-like Magnetic Field Structures Fan Guo (Los Alamos National Lab), Xiangliang.

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Presentation transcript:

Particle Acceleration at Coronal Shocks: the Effect of Large-scale Streamer-like Magnetic Field Structures Fan Guo (Los Alamos National Lab), Xiangliang Kong (Shandong University) Collaborators: Joe Giacalone (U Arizona), Hui Li (LANL), Yao Chen (SDU)

Outline Background & Motivation Numerical model & Results Summary Solar Energetic Particles (SEPs) Evidences for closed field geometry, shocks and particle acceleration low in the corona Basics of shock acceleration Sun streamer Numerical model & Results shock A coronal shock + a streamer-like field shock Summary Sun Streamer-like magnetic field can be an important factor in producing large SEPs. streamer

Solar Energetic Particles (SEPs) SEPs: energetic particles accelerated (from a few keV to up to ~GeV) near the Sun mainly during flares and coronal mass ejections. Large SEPs: proton intensity in >10 MeV GOES energy channel >10 pfu, 10 per year on average Ground Level Enhancements or GLEs: up to GeV, 16 in solar cycle 23, only 2 (3) in cycle 24, why? Large SEP events are of particular importance because… Low solar activity The detailed mechanism is not clear.

Coronal Mass Ejection (CME) Large SEPs are usually associated with CMEs and are accelerated by CME-driven shocks. Coronal Mass Ejection (CME) A very large event with a strong shock shock Reames 1999

Some important factors for large SEPs Very fast (1-2%) CMEs (Kahler 2001; Gopalswamy et al.; Mewaldt et al.; …) Magnetic connectivity to Earth (Gopalswamy et al.; Reames; …) Preceding CME or twin-CMEs (Gopalswamy et al. 2004; Li et al. 2012; Ding et al. 2013; …) Magnetic-field geometry (Tylka et al. 2005; Sandroos & Vainio 2009; Guo et al. 2010; this work; …) …… In this talk, I shall emphasize the importance of a streamer-like magnetic field to particle acceleration at coronal shocks.

Why a steamer-like magnetic field? Streamers are the most obvious structures in the corona. Many CMEs originate below a streamer or interact with streamers as propagating outwards/expanding laterally. It will affect the shock properties, not considered here. In this study, we only focus on magnetic geometry of the streamers Rouillard et al. 2016 GLE 2012/05/17 GLE 2014/01/06 Streamers are pushed away by the CME/shock streamers streamers

Evidences for shocks low in the corona Recent EUV imaging by SDO/AIA, enhancement ahead of the CME (shock at ~1.2 Rs). Associated with a type II radio burst (excited by shock-accelerated electrons, a tracer for shocks). 2010/06/13 Type II burst CME shock Ma et al. 2011

Evidence for particle acceleration low in the corona CME heights at GLE particle release time (diamond): at ~3 Rs on average for well-connected events CME heights at type II bursts onset (plus): at ~1.3-1.8 Rs Cycle 23 Gopalswamy et al. 2012 (also: Reames 2009) A shock is very likely to form and start accelerating particles well below 2 Rs.

Modeling of particle acceleration at shocks diffusion advection energy change sources Steady-state solution of the Parker equation for a 1D planar shock, downstream distribution: with Numerous SEP modeling works have been performed (Lee 1983; Ng et al. 1999; Zank et al. 2000; Li et al. 2003; Giacalone 2015; ...) Magnetic turbulence near the shock: enable particle scattering Shock geometry: acceleration rate is faster at a perp. shock than at a parallel shock (if not consider self-excited waves at parallel shocks) Basic physics have been well established over the past 40 years J. Giacalone

Particle acceleration at coronal shocks A circular shock moves with constant speed (2000 km/s) and compression ratio (X = 3). Shock center fixed at 0.1 Rs above solar surface, initial shock radius 0.2 Rs (outermost shock front at 1.3 Rs). magnetic field shock An analytical streamer-like coronal field (shock upstream). For comparison, also consider a radial magnetic field. B.C. Low 1986

Background solar wind is at rest. Consider spatial diffusion both along (parallel) and across (perp.) the magnetic field, momentum-dependent. Quasi-linear theory (Giacalone & Jokipii 1999): The diffusion across the field is generally smaller than that along the field (for p = p0, 100 keV protons) Background solar wind is at rest. Downstream magnetic field is compressed, analytically given by solving the induction equation. 100 keV protons are continuously injected upstream of the shock at a constant rate. The Parker equation is solved by a stochastic integration method.

Advantages of the model: Varying shock geometry. Consider perpendicular diffusion, important to particle acceleration at a perpendicular shock. The shock can be well resolved, necessary to get correct results. Main issues to be addressed: Can a coronal shock accelerate particles efficiently within a few solar radii? To what energies? What is the effect of a streamer-like magnetic field?

1. Energy spectrum of accelerated particles Particles can be sufficiently accelerated to >100 MeV within 2 Rs, consistent with observations (Reames 2009; Gopalswamy et al. 2012). Power-law breaks at ~100 MeV, maximum energy several hundred MeV. 3 Rs 2.5 Rs 2 Rs 1.5 Rs

Comparison with a radial magnetic field: Particle acceleration in the streamer-like field is much more efficient compared to a simple radial field (breaks at ~10 MeV). At 2 Rs, the intensity at 100 MeV is enhanced by 103. 2 Rs streamer 3 Rs radial

2. Distribution of accelerated particles 1.5 Rs 2 Rs 2.5 Rs Distribution of <10 MeV particles is generally uniform along the shock, while >90 MeV particles are concentrated at shock nose. Particles can be accelerated to ~100 MeV below 2 Rs. <10 MeV >90 MeV

What causes the difference? Perpendicular shock geometry: in a streamer-like field, first at shock nose, later at shock flanks Streamer-like field Radial field

Natural trapping effect of closed magnetic field: trap particles and help particle acceleration Mainly accelerated in close field (<2.5 Rs), to 65 p0 (~400 MeV) shock at particle injection particle trajectory

3. Provide predictions for Solar Probe Plus Energy spectrum Intensity-time profiles Intensity profiles at 10 Rs at the equator: 0.1-2.5 MeV 2.5-10 MeV 10-40 MeV 40-90 MeV >90 MeV Still working on it!

Summary We present a numerical model to study particle acceleration at coronal shocks. A coronal shock can sufficiently accelerate particles to >100 MeV within a few solar radii. Streamer-like magnetic field (or more generally, closed loops) can be an important factor in producing large SEP events. Kong et al. Particle Acceleration at Coronal Shocks: The Effect of Large-Scale Streamer-like Magnetic Field Structures, Astrophysical Journal, in preparation