Comparative study of a relativistic magnetron performance with various cathodes

Digest of Technical Papers. 12th IEEE International Pulsed Power Conference. (Cat. No.99CH36358) Pub Date : 1999-06-27 DOI:10.1109/PPC.1999.825446

Y. Saveliev, W. Sibbett, S. Spark, B. Kerr, M. I. Harbour, S. C. Douglas

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引用次数: 1

Abstract

Cathode plasma expansion into a vacuum gap is one of the major physical mechanisms affecting the relativistic magnetron (RM) performance and causing a so-called pulse shortening. Therefore, development of new cathode technologies may lead to a significant enhancement of the microwave pulse length, efficiency and power of RMs. The authors are currently conducting a series of experiments with various cathodes with an aim towards improving the RM characteristics. The first results of this research were reported at the BEAMS'98 Conference (Haifa, Israel). In this paper, a more detailed analysis of the experimental data is presented. A primary objective in this research was to determine how the cathode geometry and type of the emission surface would influence major RM characteristics such as microwave pulse duration, output power and magnetron efficiency. The authors found that the cathode geometry influences strongly the RM operation but that the type of emission surface has much less significance. The cathode end caps, which have been mostly abandoned after transition from classical to relativistic magnetrons, were shown to be able to increase the microwave power and RM efficiency without facilitating the pulse shortening effect.

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不同阴极下相对论磁控管性能的比较研究

阴极等离子体膨胀到真空间隙是影响相对论磁控管性能并导致脉冲缩短的主要物理机制之一。因此，新型阴极技术的发展可能会显著提高微波脉冲长度、效率和功率。作者目前正在用各种阴极进行一系列实验，目的是改善RM特性。这项研究的第一批结果在1998年beam会议(以色列海法)上报告。本文对实验数据进行了较为详细的分析。本研究的主要目的是确定阴极的几何形状和发射表面的类型如何影响微波脉冲持续时间，输出功率和磁控管效率等主要RM特性。结果表明，阴极几何形状对辐射场的影响较大，而发射面类型对辐射场的影响较小。在从经典磁控管过渡到相对论磁控管后，阴极端帽已被废弃，但它能在不促进脉冲缩短的情况下提高微波功率和RM效率。

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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Digest of Technical Papers. 12th IEEE International Pulsed Power Conference. (Cat. No.99CH36358)

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