太阳风中小型通量绳内超热电子的电子加速器

IF 8.8 1区 物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS
Weiduo Meng, Jianpeng Guo, Haibo Lin, Huishan Fu, Meng Zhou, Dan Zhao, Yan Chen, Linxia He, Xianghan Wang, Zelin Wang
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引用次数: 0

摘要

越来越多来自观测、理论和模拟的证据表明,在充满动态小尺度通量绳(FRs)的太阳风区域,粒子可以有效地加速。在模拟中发现的主要加速机制包括平行电场加速度、一阶费米加速度和收缩或合并小型FRs时的广义电子加速器加速度。然而,从现场测量中直接识别这些加速机制仍然是一个挑战。在这里,我们提出了一个独特的事件,在太阳风收缩的小尺度FR内,由于局部压缩,局部电子加速器加速。在这种情况下,低能的晕电子通过电子加速器机制得到了有效的加速,而以超晕成分为主的高能超热电子几乎没有被激发。利用解析模型再现了通过电子加速器机制的晕电子充能过程。对1995-2020年期间日球层电流片附近的小尺度FRs的进一步研究表明,betatron加速过程的现场特征基本上是难以捉摸的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Betatron Acceleration of Suprathermal Electrons within a Small-scale Flux Rope in the Solar Wind
Abstract A growing body of evidence from observations, theories, and simulations indicates that particles can be effectively accelerated in solar wind regions filled with dynamic small-scale flux ropes (FRs). The main acceleration mechanisms identified in simulations include parallel electric field acceleration, first-order Fermi acceleration, and generalized betatron acceleration in contracting or merging small-scale FRs. However, direct identification of these acceleration mechanisms from in situ measurements remains a challenge. Here we present a distinct event of local betatron acceleration within a contracting small-scale FR in the solar wind, due to a local compression. In this event, the lower-energy halo electrons were effectively accelerated through the betatron mechanism, whereas the higher-energy suprathermal electrons predominated by the superhalo component were almost not energized. The halo electron energization processes via the betatron mechanism are reproduced using an analytical model. Further examination of small-scale FRs in the vicinity of the heliospheric current sheet over the period 1995–2020 indicates that in situ signatures of the betatron acceleration process are essentially elusive.
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来源期刊
Astrophysical Journal Letters
Astrophysical Journal Letters ASTRONOMY & ASTROPHYSICS-
CiteScore
14.10
自引率
6.30%
发文量
513
审稿时长
2-3 weeks
期刊介绍: The Astrophysical Journal Letters (ApJL) is widely regarded as the foremost journal for swiftly disseminating groundbreaking astronomical research. It focuses on concise reports that highlight pivotal advancements in the field of astrophysics. By prioritizing timeliness and the generation of immediate interest among researchers, ApJL showcases articles featuring novel discoveries and critical findings that have a profound effect on the scientific community. Moreover, ApJL ensures that published articles are comprehensive in their scope, presenting context that can be readily comprehensible to scientists who may not possess expertise in the specific disciplines covered.
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