Steady States of a Diode with Relativistic Electron and Positron Beams

IF 1.1 4区物理与天体物理 Q4 PHYSICS, FLUIDS & PLASMAS

Plasma Physics Reports Pub Date : 2025-07-16 DOI:10.1134/S1063780X25602329

V. I. Kuznetsov, L. A. Bakaleinikov, I. K. Morozov, E. Yu. Flegontova

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Abstract

The steady states of a diode in which electrons and positrons come from opposite electrodes with relativistic velocities have been studied. Such a situation may occur, e.g., in the plasma of pulsar diodes. Both the mode when charged particles reach the opposite electrode and the mode when a portion of particles is reflected by the potential barriers within the inter-electrode gap are considered. It is established that with a fixed potential difference between the electrodes, the solutions are determined by only three dimensionless parameters: the inter-electrode distance \(\delta \), the relativistic factor of the entering electrons \({{\gamma }_{0}}\), and the electric field strength at the left electrode \({{\varepsilon }_{0}}\). The whole variety of solutions is represented by a set of curves in \(\{ {{\varepsilon }_{0}},\delta \} \) plane. It turned out that these curves qualitatively coincide with the branches of the solutions in the non-relativistic case. The relativistic factor effect on structure of the solution branches has been analysed.

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具有相对论性电子束和正电子束的二极管的稳态

本文研究了电子和正电子以相对论速度从相对电极来的二极管的稳态。这种情况可能发生，例如在脉冲星二极管的等离子体中。考虑了带电粒子到达对极时的模式和部分粒子被电极间隙内的势垒反射时的模式。建立了当电极间电位差固定时，溶液仅由三个无量纲参数决定：电极间距离\(\delta \)、进入电子的相对论性因子\({{\gamma }_{0}}\)和左电极处的电场强度\({{\varepsilon }_{0}}\)。所有的解都用\(\{ {{\varepsilon }_{0}},\delta \} \)平面上的一组曲线表示。结果证明，在非相对论情况下，这些曲线在性质上与解的分支重合。分析了相对论性因素对溶液分支结构的影响。

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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来源期刊

Plasma Physics Reports 物理-物理：流体与等离子体

CiteScore

1.90

自引率

36.40%

发文量

104

审稿时长

4-8 weeks

期刊介绍： Plasma Physics Reports is a peer reviewed journal devoted to plasma physics. The journal covers the following topics: high-temperature plasma physics related to the problem of controlled nuclear fusion based on magnetic and inertial confinement; physics of cosmic plasma, including magnetosphere plasma, sun and stellar plasma, etc.; gas discharge plasma and plasma generated by laser and particle beams. The journal also publishes papers on such related topics as plasma electronics, generation of radiation in plasma, and plasma diagnostics. As well as other original communications, the journal publishes topical reviews and conference proceedings.