Calculation of the electron velocity distribution function in a plasma slab with large temperature and density gradients

N. Ljepojevic, A. Burgess
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引用次数: 27

Abstract

A detailed description is given of a new method for calculating the high- velocity tail of the electron velocity distribution function in a plasma slab with large temperature and density gradients. Thermal electrons in a plasma are strongly coupled with each other and in a steady state their velocity distribution is always near to maxwellian. On the other hand, the collision frequency of an electron decreases rapidly with increasing speed (v ~ v-3), so that the coupling between the high-velocity electrons and the plasma is very weak. These electrons move almost freely through the plasma and an inhomogeneity can strongly affect the high-velocity part of the distribution function. In our method electrons are classified into two groups, depending on their velocity. The distribution function for the first group (thermal electrons) is accurately given by the Spitzer-Harm solution of the Landau-Fokker-Planck equation. For the second group (high-velocity electrons) the Spitzer-Harm solution is inaccurate and we calculate the distribution function as a solution to the high-velocity approximation of the Landau-Fokker-Planck equation (HVL). The two solutions are matched at a suitably chosen value of the normalized speed ξ. We solve the HVL equation numerically using an efficient method that we have developed. Application is made to the transition region of the quiet Sun using several data-sets for temperature and density gradients by different authors. The results exhibit large deviations from maxwellian throughout the transition region as well as a strongly anisotropic character of the high-velocity tail of the distribution function. The results are very sensitive to the gradients. Also, the non-local character of the formation of the velocity distribution is clearly seen.
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具有大温度和密度梯度的等离子体板中电子速度分布函数的计算
详细介绍了一种计算具有大温度和密度梯度的等离子体平板中电子速度分布函数高速尾的新方法。等离子体中的热电子相互之间是强耦合的,在稳定状态下它们的速度分布总是接近麦克斯韦定律。另一方面,电子的碰撞频率随着速度的增加而迅速降低(v ~ v-3),使得高速电子与等离子体之间的耦合非常弱。这些电子在等离子体中几乎自由移动,不均匀性会强烈影响分布函数的高速部分。在我们的方法中,根据电子的速度把它们分成两组。第一组(热电子)的分布函数由Landau-Fokker-Planck方程的Spitzer-Harm解精确给出。对于第二组(高速电子),Spitzer-Harm解是不准确的,我们计算了分布函数作为Landau-Fokker-Planck方程(HVL)的高速近似解。这两个解以适当选择的归一化速度ξ值进行匹配。我们利用自己开发的一种有效方法对HVL方程进行了数值求解。不同的作者使用不同的温度和密度梯度数据集对平静太阳的过渡区域进行了应用。结果表明,在整个过渡区与麦克斯韦方程存在较大的偏差,分布函数的高速尾部具有很强的各向异性特征。结果对梯度非常敏感。同时,速度分布形成的非局域性也很明显。
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