Your search keyword '"Guo, Fan"' showing total 7 results

1. Magnetic Reconnection and Associated Particle Acceleration in High-Energy Astrophysics

Author

Guo, Fan, Liu, Yi-Hsin, Zenitani, Seiji, and Hoshino, Masahiro

Published

2024

2. Particle Acceleration by Magnetic Reconnection in Geospace

Author

Oka, Mitsuo, Birn, Joachim, Egedal, Jan, Guo, Fan, Ergun, Robert E., Turner, Drew L., Khotyaintsev, Yuri, Hwang, Kyoung-Joo, Cohen, Ian J., and Drake, James F.

Published

2023

3. Particle Injection and Nonthermal Particle Acceleration in Relativistic Magnetic Reconnection.

Author

French, Omar, Guo, Fan, Zhang, Qile, and Uzdensky, Dmitri A.

Subjects

*MAGNETIC reconnection, *PARTICLE acceleration, *RELATIVISTIC particles, *MAGNETIC fields, *ELECTRIC fields, *COLLISIONLESS plasmas, *NEBULAE

Abstract

Magnetic reconnection in the relativistic regime has been proposed as an important process for the efficient production of nonthermal particles and high-energy emission. Using fully kinetic particle-in-cell simulations, we investigate how the guide-field strength and domain size affect the characteristic spectral features and acceleration processes. We study two stages of acceleration: energization up until the injection energy γ inj and further acceleration that generates a power-law spectrum. Stronger guide fields increase the power-law index and γ inj, which suppresses acceleration efficiency. These quantities seemingly converge with increasing domain size, suggesting that our findings can be extended to large-scale systems. We find that three distinct mechanisms contribute to acceleration during injection: particle streaming along the parallel electric field, Fermi reflection, and the pickup process. The Fermi and pickup processes, related to the electric field perpendicular to the magnetic field, govern the injection for weak guide fields and larger domains. Meanwhile, parallel electric fields are important for injection in the strong guide-field regime. In the post-injection stage, we find that perpendicular electric fields dominate particle acceleration in the weak guide-field regime, whereas parallel electric fields control acceleration for strong guide fields. These findings will help explain the nonthermal acceleration and emission in high-energy astrophysics, including black hole jets and pulsar wind nebulae. [ABSTRACT FROM AUTHOR]

Published

2023

4. A Model of Double Coronal Hard X-Ray Sources in Solar Flares.

Author

Kong, Xiangliang, Ye, Jing, Chen, Bin, Guo, Fan, Shen, Chengcai, Li, Xiaocan, Yu, Sijie, Chen, Yao, and Giacalone, Joe

Subjects

HARD X-rays, SOLAR flares, TRANSPORT equation, ELECTRON transport, PARTICLE acceleration, MAGNETIC fields, MAGNETIC reconnection

Abstract

A number of double coronal X-ray sources have been observed during solar flares by RHESSI, where the two sources reside at different sides of the inferred reconnection site. However, where and how these X-ray-emitting electrons are accelerated remains unclear. Here we present the first model of the double coronal hard X-ray (HXR) sources, where electrons are accelerated by a pair of termination shocks driven by bidirectional fast reconnection outflows. We model the acceleration and transport of electrons in the flare region by numerically solving the Parker transport equation using velocity and magnetic fields from the macroscopic magnetohydrodynamic simulation of a flux rope eruption. We show that electrons can be efficiently accelerated by the termination shocks and high-energy electrons mainly concentrate around the two shocks. The synthetic HXR emission images display two distinct sources extending to >100 keV below and above the reconnection region, with the upper source much fainter than the lower one. The HXR energy spectra of the two coronal sources show similar spectral slopes, consistent with the observations. Our simulation results suggest that the flare termination shock can be a promising particle acceleration mechanism in explaining the double-source nonthermal emissions in solar flares. [ABSTRACT FROM AUTHOR]

Published

2022

5. Particle Acceleration in Magnetic Reconnection with Ad Hoc Pitch-angle Scattering.

Author

Johnson, Grant, Kilian, Patrick, Guo, Fan, and Li, Xiaocan

Subjects

MAGNETIC reconnection, MAGNETIC particles, PLASMA astrophysics, PARTICLE acceleration, SKYRMIONS, FERMI energy, SOLAR corona

Abstract

Particle acceleration during magnetic reconnection is a long-standing topic in space, solar, and astrophysical plasmas. Recent 3D particle-in-cell simulations of magnetic reconnection show that particles can leave flux ropes due to 3D field-line chaos, allowing particles to access additional acceleration sites, gain more energy through Fermi acceleration, and develop a power-law energy distribution. This 3D effect does not exist in traditional 2D simulations, where particles are artificially confined to magnetic islands due to their restricted motions across field lines. Full 3D simulations, however, are prohibitively expensive for most studies. Here, we attempt to reproduce 3D results in 2D simulations by introducing ad hoc pitch-angle scattering to a small fraction of the particles. We show that scattered particles are able to transport out of 2D islands and achieve more efficient Fermi acceleration, leading to a significant increase of energetic particle flux. We also study how the scattering frequency influences the nonthermal particle spectra. This study helps achieve a complete picture of particle acceleration in magnetic reconnection. [ABSTRACT FROM AUTHOR]

Published

2022

6. Radiation and Polarization Signatures from Magnetic Reconnection in Relativistic Jets. II. Connection with γ-Rays.

Author

Zhang, Haocheng, Li, Xiaocan, Giannios, Dimitrios, Guo, Fan, Thiersen, Hannes, Böttcher, Markus, Lewis, Tiffany, and Venters, Tonia

Subjects

MAGNETIC reconnection, PARTICLE acceleration, NEUTRINOS, SUPERMASSIVE black holes, OPTICAL polarization, RADIATION, BREWSTER'S angle

Abstract

It is commonly believed that blazar jets are relativistic magnetized plasma outflows from supermassive black holes. One key question is how the jets dissipate magnetic energy to accelerate particles and drive powerful multiwavelength flares. Relativistic magnetic reconnection has been proposed as the primary plasma physical process in the blazar emission region. Recent numerical simulations have shown strong acceleration of nonthermal particles that may lead to multiwavelength flares. Nevertheless, previous works have not directly evaluated γ-ray signatures from first-principles simulations. In this paper, we employ combined particle-in-cell and polarized radiation transfer simulations to study multiwavelength radiation and optical polarization signatures under the leptonic scenario from relativistic magnetic reconnection. We find harder-when-brighter trends in optical and Fermi-LAT γ-ray bands as well as closely correlated optical and γ-ray flares. The swings in optical polarization angle are also accompanied by γ-ray flares with trivial time delays. Intriguingly, we find highly variable synchrotron self-Compton signatures due to inhomogeneous particle distributions during plasmoid mergers. This feature may result in fast γ-ray flares or orphan γ-ray flares under the leptonic scenario, complementary to the frequently considered minijet scenario. It may also imply neutrino emission with low secondary synchrotron flux under the hadronic scenario, if plasmoid mergers can accelerate protons to very high energy. [ABSTRACT FROM AUTHOR]

Published

2022

7. Magnetic Energy Release, Plasma Dynamics, and Particle Acceleration in Relativistic Turbulent Magnetic Reconnection.

Author

Guo, Fan, Li, Xiaocan, Daughton, William, Li, Hui, Kilian, Patrick, Liu, Yi-Hsin, Zhang, Qile, and Zhang, Haocheng

Subjects

*MAGNETIC reconnection, *PLASMA dynamics, *RELATIVISTIC particles, *PARTICLE acceleration, *CURRENT sheets, *PLASMA astrophysics

Abstract

In strongly magnetized astrophysical plasma systems, magnetic reconnection is believed to be the primary process during which explosive energy release and particle acceleration occur, leading to significant high-energy emission. Past years have witnessed active development of kinetic modeling of relativistic magnetic reconnection, supporting this magnetically dominated scenario. A much less explored issue in studies of relativistic reconnection is the consequence of three-dimensional dynamics, where turbulent structures are naturally generated as various types of instabilities develop. This paper presents a series of three-dimensional, fully kinetic simulations of relativistic turbulent magnetic reconnection (RTMR) in positronâ€"electron plasmas with system domains much larger than kinetic scales. Our simulations start from a force-free current sheet with several different modes of long-wavelength magnetic field perturbations, which drive additional turbulence in the reconnection region. Because of this, the current layer breaks up and the reconnection region quickly evolves into a turbulent layer filled with coherent structures such as flux ropes and current sheets. We find that plasma dynamics in RTMR is vastly different from its 2D counterpart in many aspects. The flux ropes evolve rapidly after their generation, and can be completely disrupted by the secondary kink instability. This turbulent evolution leads to superdiffusive behavior of magnetic field lines as seen in MHD studies of turbulent reconnection. Meanwhile, nonthermal particle acceleration and the timescale for energy release can be very fast and do not depend strongly on the turbulence amplitude. The main acceleration mechanism is a Fermi-like acceleration process supported by the motional electric field, whereas the nonideal electric field acceleration plays a subdominant role. We also discuss possible observational implications of three-dimensional RTMR in high-energy astrophysics. [ABSTRACT FROM AUTHOR]

Published

2021