Asymptotic-preserving gyrokinetic implicit particle-orbit integrator for arbitrary electromagnetic fields

arXiv - CS - Numerical Analysis Pub Date : 2023-12-01 DOI:arxiv-2312.00730

Lee Ricketson, Luis Chacón

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Abstract

We extend the asymptotic preserving and energy conserving time integrator for charged-particle motion developed in [Ricketson & Chac\'on, JCP, 2020] to include finite Larmor-radius (FLR) effects in the presence of electric-field length-scales comparable to the particle gyro-radius (the gyro-kinetic limit). We introduce two modifications to the earlier scheme. The first is the explicit gyro-averaging of the electric field at the half time-step, along with an analogous modification to the current deposition, which we show preserves total energy conservation in implicit PIC schemes. The number of gyrophase samples is chosen adaptively, ensuring proper averaging for large timesteps, and the recovery of full-orbit dynamics in the small time-step limit. The second modification is an alternating large and small time-step strategy that ensures the particle trajectory samples gyrophases evenly. We show that this strategy relaxes the time-step restrictions on the scheme, allowing even larger speed-ups than previously achievable. We demonstrate the new method with several single-particle motion tests in a variety of electromagnetic field configurations featuring gyro-scale variation in the electric field. The results demonstrate the advertised ability to capture FLR effects accurately even when significantly stepping over the gyration time-scale.

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任意电磁场的渐近保持陀螺动力学隐式粒子轨道积分器

我们扩展了[Ricketson & Chac\'on, JCP, 2020]中开发的带电粒子运动的渐近保持和节能时间积分器，以包括与粒子陀螺半径(陀螺动力学极限)相当的电场长度尺度下的有限larmorr -半径(FLR)效应。我们对先前的方案作了两个修改。第一个是在半时间步的显式电场平均，以及对电流沉积的类似修改，我们表明在隐式PIC方案中保留了总能量守恒。自适应地选择了陀螺相位样本的数量，保证了大时间步长的平均，以及小时间步长的全轨道动力学恢复。第二次修正是采用大、小时间步长交替策略，保证粒子轨迹采样陀螺相位均匀。我们表明，该策略放宽了对方案的时间步长限制，允许比以前可实现的更大的加速。我们用几个单粒子运动测试证明了新方法在各种电磁场配置中具有陀螺尺度变化的电场。结果表明，即使在显著跨越旋转时间尺度时，也能准确捕获FLR效应。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - CS - Numerical Analysis

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