Compact Ion Beam System for Fusion Demonstration

Q2 Physics and Astronomy
Allan Xi Chen , Nai-Wei Liu , Alexander Gunn , Zhe Su , Benjamin F. Sigal , Matthew Salazar , Nawar Abdalla , James Chen , Alfred Y. Wong , Qiong Wang
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引用次数: 0

Abstract

We demonstrate a compact ion beam device capable of accelerating H+ and D+ ions up to 75 keV energy, onto a solid target, with sufficient beam current to study fusion reactions. The ion beam system uses a microwave driven plasma source to generate ions that are accelerated to high energy with a direct current (DC) acceleration structure. The plasma source is driven by pulsed microwaves from a solid-state radiofrequency (RF) amplifier, which is impedance matched to the plasma source chamber at the S-band frequency in the range of 2.4–2.5 GHz. The plasma chamber is held at high positive DC potential and is isolated from the impedance matching structure (at ground potential) by a dielectric-filled gap. To facilitate the use of high-energy-particle detectors near the target, the plasma chamber is biased to a high positive voltage, while the target remains grounded. A target loaded with deuterium is used to study D-D fusion and a B4C or LaB6 target is used to study p-11B fusion. Detectors include solid-state charged particle detector and a scintillation fast neutron detector. The complete ion beam system can fit on a laboratory table and is a useful tool for teaching undergraduate and graduate students about the physics of fusion.

用于聚变演示的紧凑型离子束系统
我们展示了一种结构紧凑的离子束装置,能够将 H+ 和 D+ 离子加速到 75 keV 的能量,并以足够的束流照射到固体靶上,以研究核聚变反应。离子束系统使用微波驱动等离子源产生离子,通过直流(DC)加速结构将离子加速到高能量。等离子源由一个固态射频(RF)放大器发出的脉冲微波驱动,该放大器在 2.4-2.5 千兆赫的 S 波段频率上与等离子源室阻抗匹配。等离子体室保持在高正向直流电位,并通过填充介质的间隙与阻抗匹配结构(接地电位)隔离。为了便于在靶附近使用高能粒子探测器,等离子体室被偏置为高正向电压,而靶则保持接地状态。装有氘的靶用于研究 D-D 核聚变,B4C 或 LaB6 靶用于研究 p-11B 核聚变。探测器包括固态带电粒子探测器和闪烁快中子探测器。整个离子束系统可以放在实验室的桌子上,是向本科生和研究生传授核聚变物理学知识的有用工具。
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
Physics Open
Physics Open Physics and Astronomy-Physics and Astronomy (all)
CiteScore
3.20
自引率
0.00%
发文量
19
审稿时长
9 weeks
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