Inductive voltage adder driven X-ray sources for hydrodynamic radiography

Digest of Technical Papers. 12th IEEE International Pulsed Power Conference. (Cat. No.99CH36358) Pub Date : 1999-06-27 DOI:10.1109/PPC.1999.825465

J. Maenchen, S. Cordova, J. Gustwiller, D.L. Johnson, P. Menge, I. Molina, C. Olson, S. Rosenthal, D. Rovang, O. Oliver, D. Welch, V. Bailey, I. Smith, D. Droemer, E. Hunt, G. Macleod, L. Woo

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引用次数: 17

Abstract

Inductive voltage adder (IVA) accelerators were developed to provide high-current (100s of kA) power pulses at high voltage (up to 20 MV) using robust modular components. This architecture simultaneously resolves problems found in conventional pulsed and linear induction accelerators. A variety of high-brightness pulsed X-ray radiographic sources are needed from submegavolt to 16-MeV endpoints with greater source brightness (dose/spot/sup 2/) than presently available. We are applying IVA systems to produce very intense (up to 75 TW/cm/sup 2/) electron beams for these flash radiographic applications. The accelerator electromagnetic pulse is converted to a directed electron beam at the end of a self-magnetically insulated vacuum transmission line. The cantilevered cathode threading the accelerator cavities terminates in a small (l-mm diameter) needle, producing the electron beam which is transported to a grounded Bremsstrahlung converter within a strong (/spl sim/50 T) axial magnetic field. These systems produce mm-sized stable electron beams, yielding very intense X-ray sources. Detailed simulations of the electron beam generation, transport, and target interaction are presented along with scaling laws for the radiation production and X-ray spot size. Experimental studies confirm these simulations and show this reliable, compact, and inexpensive technology scales to 1000-R doses a meter from a mm-diameter source in 50 ns.

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水动力射线照相用电感电压加法器驱动的x射线源

电感电压加法器(IVA)加速器采用坚固的模块化组件，在高电压(高达20 MV)下提供大电流(100 kA)功率脉冲。这种结构同时解决了传统脉冲和线性感应加速器存在的问题。从亚兆伏特到16兆电子伏的各种高亮度脉冲x射线射线源需要比目前可用的更高的光源亮度(剂量/光斑/sup /)。我们正在应用IVA系统为这些闪光射线照相应用产生非常强的电子束(高达75 TW/cm/sup 2/)。加速器电磁脉冲在自磁绝缘真空传输线末端转化为定向电子束。穿过加速器腔的悬臂式阴极在一个直径为l-mm的小针中终止，产生电子束，电子束在强(/spl sim/50 T)轴向磁场中被输送到接地的轫致变换器。这些系统产生毫米大小的稳定电子束，产生非常强烈的x射线源。详细模拟了电子束的产生、传输和目标相互作用，并给出了辐射产生和x射线光斑尺寸的标度规律。实验研究证实了这些模拟，并表明这种可靠、紧凑和廉价的技术可在50毫纳秒内达到距离毫米直径源1米的1000 r剂量。

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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