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Electron stochastic acceleration in laboratory-produced kinetic turbulent plasmas.

Dawei YuanZhu LeiHuigang WeiZhe ZhangJiayong ZhongYifei LiYongli PingYihang ZhangYu-Tong LiFeilu WangGuiyun LiangBin QiaoChangbo FuHuiya LiuPanzheng ZhangJianqiang ZhuGang ZhaoJie Zhang
Published in: Nature communications (2024)
The origin of energetic charged particles in universe remains an unresolved issue. Astronomical observations combined with simulations have provided insights into particle acceleration mechanisms, including magnetic reconnection acceleration, shock acceleration, and stochastic acceleration. Recent experiments have also confirmed that electrons can be accelerated through processes such as magnetic reconnection and collisionless shock formation. However, laboratory identifying stochastic acceleration as a feasible mechanism is still a challenge, particularly in the creation of collision-free turbulent plasmas. Here, we present experimental results demonstrating kinetic turbulence with a typical spectrum k -2.9 originating from Weibel instability. Energetic electrons exhibiting a power-law distribution are clearly observed. Simulations further reveal that thermal electrons undergo stochastic acceleration through collisions with multiple magnetic islands-like structures within the turbulent region. This study sheds light on a critical transition period during supernova explosion, where kinetic turbulences originating from Weibel instability emerge prior to collisionless shock formation. Our results suggest that electrons undergo stochastic acceleration during this transition phase.
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