漂移相分辨扩散辐射带模型:2。电势随机波动情况下的实现

IF 2.6 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS Frontiers in Astronomy and Space Sciences Pub Date : 2023-08-08 DOI:10.3389/fspas.2023.1232512
S. Lejosne, J. Albert, S. Walton
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引用次数: 1

摘要

在这项工作的第一部分中,我们强调了一个漂移扩散方程,该方程能够在描述捕获粒子输运对辐射带强度的影响时解决磁局部时间维度。在这里,我们在特殊情况下执行这些一般性考虑。具体来说,我们确定了在特定的时变电场模型存在的情况下,求解在偶极磁场中漂移的赤道电子的漂移-扩散方程所需的各种传输和扩散系数。随机电位波动,被描述为白噪声,驱动捕获粒子漂移运动的波动。我们还进行了一个数值实验,包括跟踪被捕获粒子的漂移运动。我们使用这些结果来说明漂移扩散方程的有效性,通过显示解的一致性。我们的研究结果描述了一个最初定位在磁局部时间的结构如何产生漂移周期性特征,由于径向和方位角扩散的综合影响,漂移周期性信号随时间逐渐衰减。换言之,我们模拟了从漂移主导的制度向扩散主导的制度的转变。我们还证明,一旦分布函数相混合,漂移扩散方程就等价于标准径向扩散方程。一旦确定了包括局部输运和扩散系数在内的现实输入,漂移-扩散方程将允许辐射带建模具有比径向扩散模型更好的时空分辨率。
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Drift phase resolved diffusive radiation belt model: 2. implementation in a case of random electric potential fluctuations
In the first part of this work, we highlighted a drift-diffusion equation capable of resolving the magnetic local time dimension when describing the effects of trapped particle transport on radiation belt intensity. Here, we implement these general considerations in a special case. Specifically, we determine the various transport and diffusion coefficients required to solve the drift-diffusion equation for equatorial electrons drifting in a dipole magnetic field in the presence of a specific model of time-varying electric fields. Random electric potential fluctuations, described as white noise, drive fluctuations of trapped particle drift motion. We also run a numerical experiment that consists of tracking trapped particles’ drift motion. We use the results to illustrate the validity of the drift-diffusion equation by showing agreement in the solutions. Our findings depict how a structure initially localized in magnetic local time generates drift-periodic signatures that progressively dampen with time due to the combined effects of radial and azimuthal diffusions. In other words, we model the transition from a drift-dominated regime, to a diffusion-dominated regime. We also demonstrate that the drift-diffusion equation is equivalent to a standard radial diffusion equation once the distribution function is phase-mixed. The drift-diffusion equation will allow for radiation belt modeling with a better spatiotemporal resolution than radial diffusion models once realistic inputs, including localized transport and diffusion coefficients, are determined.
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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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