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1. Magnetic-Field-Driven Electron Dynamics in Graphene

   https://doi.org/10.1021/acs.jpclett.1c01020  

   Fatima, F.; Inerbaev, T; Xia, W; Kilin, D. (May 2021, The journal of physical chemistry letters)

   null (Ed.)

   Graphene exhibits unique optoelectronic properties originating from the band structure at the Dirac points. It is an ideal model structure to study the electronic and optical properties under the influence of the applied magnetic field. In graphene, electric field, laser pulse, and voltage can create electron dynamics which is influenced by momentum dispersion. However, computational modeling of momentum-influenced electron dynamics under the applied magnetic field remains challenging. Here, we perform computational modeling of the photoexcited electron dynamics achieved in graphene under an applied magnetic field. Our results show that magnetic field leads to local deviation from momentum conservation for charge carriers. With the increasing magnetic field, the delocalization of electron probability distribution increases and forms a cyclotron-like trajectory. Our work facilitates understanding of momentum resolved magnetic field effect on non-equilibrium properties of graphene, which is critical for optoelectronic and photovoltaic applications. 

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2. Modeling electron acceleration during the contraction of a magnetic island

   https://doi.org/10.1088/1742-6596/2742/1/012015  

   Deuja, Atit; Che, Haihong (April 2024, Journal of Physics: Conference Series)

   Abstract Magnetic reconnection releases the magnetic energy through the contraction of multi-magnetic island leading to the electron acceleration as proposed by Drake et. al in 2006. However, how the released magnetic energy is converted into electron’s kinetic energy is still theoretically not well understood. We model in particular the kinetic process assuming the adiabatic contraction of magnetic island that induces electric field which is proportional to the vector potential of the magnetic island and approximate the magnetic island with an ellipse. Under this model, we show that the energy gain is achieved through the work of inductive electric field. We further show that the curvature drift which is along the inductive electric field dominates the energy gain. We compared our model with the magnetic island formed by tearing instability in a 2.5D particle-in-cell simulation of magnetic reconnection and found the results from the model consistent with that of the simulation. 

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3. Kinetic theory of the electron strahl in the solar wind

   https://doi.org/10.1093/mnras/stz2378  

   Boldyrev, Stanislav; Horaites, Konstantinos (November 2019, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT We develop a kinetic theory for the electron strahl, a beam of energetic electrons which propagate from the sun along the Parker-spiral-shaped magnetic field lines. Assuming a Maxwellian electron distribution function in the near-sun region where the plasma is collisional, we derive the strahl distribution function at larger heliospheric distances. We consider the two most important mechanisms that broaden the strahl: Coulomb collisions and interactions with oblique ambient whistler turbulence (anomalous diffusion). We propose that the energy regimes where these mechanisms are important are separated by an approximate threshold, $${\cal E}_\mathrm{ c}$$; for the electron kinetic energies $${\cal E}\,\lt\, {\cal E}_\mathrm{ c}$$ the strahl width is mostly governed by Coulomb collisions, while for $${\cal E}\,\gt\, {\cal E}_\mathrm{ c}$$ by interactions with the whistlers. The Coulomb broadening decreases as the electron energy increases; the whistler-dominated broadening, on the contrary, increases with energy and it can lead to efficient isotropization of energetic electrons and to the formation of the electron halo. The threshold energy $${\cal E}_\mathrm{ c}$$ is relatively high in the regions closer to the sun, and it gradually decreases with the distance, implying that the anomalous diffusion becomes progressively more important at large heliospheric distances. At 1 au, we estimate the energy threshold to be about $${\cal E}_\mathrm{ c}\,\sim\, 200\, {\rm eV}$$. 

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4. Magnetospheric Multiscale (MMS) Observations of Magnetic Reconnection in Foreshock Transients

   https://doi.org/10.1029/2020JA027822  

   Liu, Terry Z.; Lu, San; Turner, Drew L.; Gingell, Imogen; Angelopoulos, Vassilis; Zhang, Hui; Artemyev, Anton; Burch, James L. (April 2020, Journal of Geophysical Research: Space Physics)

   Abstract Magnetic reconnection is a fundamental process of energy conversion in plasmas between electromagnetic fields and particles. Magnetic reconnection has been observed directly in a variety of plasmas in the solar wind and Earth's magnetosphere. Most recently, electron magnetic reconnection without ion coupling was observed for the first time in the turbulent magnetosheath and within the transition region of Earth's bow shock. In the ion foreshock upstream of Earth's bow shock, there may also be magnetic reconnection especially around foreshock transients that are very turbulent and dynamic. With observations from the National Aeronautics and Space Administration's Magnetospheric Multiscale mission inside foreshock transients, we report two events of magnetic reconnection with and without a strong guide field, respectively. In both events, a super‐ion‐Alfvénic electron jet was observed within a current sheet with thickness less than or comparable to one ion inertial length. In both events, energy was converted from the magnetic field to electrons, manifested as an increase in electron temperature. Weak or no ion coupling was observed in either event. Results from particle‐in‐cell simulations of magnetic reconnection with and without a strong guide field are qualitatively consistent with observations. Our results imply that magnetic reconnection is another electron acceleration/heating process inside foreshock transients and could play an important role in shock dynamics. 

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5. Particle Acceleration in Relativistic Alfvénic Turbulence

   https://doi.org/10.3847/1538-4357/ad5f8f  

   Vega, Cristian; Boldyrev, Stanislav; Roytershteyn, Vadim (August 2024, The Astrophysical Journal)

   Abstract Strong magnetically dominated Alfvénic turbulence is an efficient engine of nonthermal particle acceleration in a relativistic collisionless plasma. We argue that in the limit of strong magnetization, the type of energy distribution attained by accelerated particles depends on the relative strengths of turbulent fluctuationsδB₀and the guide fieldB₀. IfδB₀≪B₀, the particle magnetic moments are conserved, and the acceleration is provided by magnetic curvature drifts. Curvature acceleration energizes particles in the direction parallel to the magnetic field lines, resulting in log-normal tails of particle energy distribution functions. Conversely, ifδB₀≳B₀, interactions of energetic particles with intense turbulent structures can scatter particles, creating a population with large pitch angles. In this case, magnetic mirror effects become important, and turbulent acceleration leads to power-law tails of the energy distribution functions. 

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