等离子体层和羽流中嘶嘶波的深度学习模型及其对辐射带电子的影响

IF 2.6 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS Frontiers in Astronomy and Space Sciences Pub Date : 2023-08-23 DOI:10.3389/fspas.2023.1231578
Sheng Huang, Wen Li, Q. Ma, Xiaochen Shen, L. Capannolo, M. Hanzelka, X. Chu, Donglai Ma, J. Bortnik, S. Wing
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引用次数: 0

摘要

嘶嘶波通过将地球辐射带中的高能电子沉降到高层大气中,在将这些电子从地球辐射带中移除方面发挥着重要作用。与已被广泛研究的等离子体嘶嘶相比,羽流嘶嘶的演变和影响尚不清楚,因为难以获得高节奏的全球观测结果。在这项研究中,我们使用神经网络方法来模拟等离子体层和羽流中总电子密度和嘶嘶波振幅的全球演变。在描述了模型的发展之后,我们将该模型应用于2019年5月14日发生的一次风暴事件,发现嘶嘶波振幅在黎明时首先增加,然后向黄昏转移,在一个高密度的狭窄区域内进一步激发,即等离子体羽流。在风暴的恢复阶段,羽流旋转并环绕地球,而嘶嘶波的振幅在夜面迅速衰减。此外,我们还模拟了整个风暴过程中高能电子的演化过程,模拟的通量衰减率与观测结果吻合较好。通过分离等离子体波和羽流嘶嘶波,我们量化了羽流嘶嘶对高能电子动力学的影响。我们的模拟表明,在相对安静的地磁条件下,羽流嘶嘶的区域可以在L = 4到6之间变化,并且可以解释在3天内数百keV的电子通量减少80%。这项研究强调了在未来的辐射带电子动力学模拟中包含动态嘶嘶分布的重要性。
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Deep learning model of hiss waves in the plasmasphere and plumes and their effects on radiation belt electrons
Hiss waves play an important role in removing energetic electrons from Earth’s radiation belts by precipitating them into the upper atmosphere. Compared to plasmaspheric hiss that has been studied extensively, the evolution and effects of plume hiss are less understood due to the challenge of obtaining their global observations at high cadence. In this study, we use a neural network approach to model the global evolution of both the total electron density and the hiss wave amplitudes in the plasmasphere and plume. After describing the model development, we apply the model to a storm event that occurred on 14 May 2019 and find that the hiss wave amplitude first increased at dawn and then shifted towards dusk, where it was further excited within a narrow region of high density, namely, a plasmaspheric plume. During the recovery phase of the storm, the plume rotated and wrapped around Earth, while the hiss wave amplitude decayed quickly over the nightside. Moreover, we simulated the overall energetic electron evolution during this storm event, and the simulated flux decay rate agrees well with the observations. By separating the modeled plasmaspheric and plume hiss waves, we quantified the effect of plume hiss on energetic electron dynamics. Our simulation demonstrates that, under relatively quiet geomagnetic conditions, the region with plume hiss can vary from L = 4 to 6 and can account for up to an 80% decrease in electron fluxes at hundreds of keV at L > 4 over 3 days. This study highlights the importance of including the dynamic hiss distribution in future simulations of radiation belt electron dynamics.
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来源期刊
Frontiers in Astronomy and Space Sciences
Frontiers in Astronomy and Space Sciences ASTRONOMY & ASTROPHYSICS-
CiteScore
3.40
自引率
13.30%
发文量
363
审稿时长
14 weeks
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