Shimou Wang scite author profile

Magnetic reconnection is a fundamental plasma process that explosively converts magnetic energy into plasma kinetic energy and produces energetic electrons in various plasma environments (Yamada et al., 2010). Observations in the solar atmosphere (Benz, 2017;Lin, 2011) and the Earth's magnetosphere (X. Li et al., 2022;Oieroset et al., 2002;Oka et al., 2016) indicate that these energetic electrons generally have a power-law distribution. Understanding the acceleration mechanisms for these electrons is a long-standing question in the study of reconnection. Previous studies have shown that flux ropes (FRs) or magnetic islands in two-dimensional cases likely play a critical role in accelerating electrons (

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Turbulent magnetic reconnection in the solar wind

Wang¹,

Li²,

Wang³

et al. 2023

Preprint

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<p>Turbulent magnetic reconnection was observed in the magnetotail and the magnetopause. In turbulent magnetic reconnection, the diffusion region is filled with a number of filamentary currents primarily carried by the electrons and some flux ropes. These dynamic filamentary currents constitute a kind of three-dimensional network in the diffusion region and lead the reconnection into turbulence. The electrons are trapped and sufficiently accelerated inside such a complicated current network.</p><p>According to the previous observations, magnetic reconnection generally displays a quasi-steady state in the solar wind, where the energy is dissipated via slow-mode shocks. It is elusive why the reconnection in the solar wind is quasi-steady. Here we present a direct observation of bursty and turbulent magnetic reconnection in the solar wind, with its associated exhausts bounded by a pair of slow-mode shocks. We infer that the plasma is more efficiently heated in the magnetic reconnection diffusion region than across the shocks and that the flow enhancement is much higher in the exhausts than in the area around the diffusion region. We detected 75 other, similar diffusion-region events in solar wind data between October 2017 and May 2019, suggesting that bursty reconnection in the solar wind is more common than previously thought and actively contributes to solar wind acceleration and heating.</p>

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Shimou Wang

Direct observation of turbulent magnetic reconnection in the solar wind

Electron Acceleration by Interaction of Two Filamentary Currents Within a Magnetopause Magnetic Flux Rope

Turbulent magnetic reconnection in the solar wind

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