利用锥形玻璃通道稳定提高电子束电流密度的可能性研究

IF 0.6 4区 材料科学 Q4 MATERIALS SCIENCE, CERAMICS Glass and Ceramics Pub Date : 2024-11-12 DOI:10.1007/s10717-024-00705-x
K. A. Vokhmyanina, A. D. Pyatigor, V. S. Sotnikova
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引用次数: 0

摘要

对于带正电荷的离子而言,通过锥形玻璃通道提高带电粒子束的电流密度(聚焦)而无需使用外部能源的可能性如今已被积极地付诸实施。对于电子束来说,由于缺乏电子束与介质表面滑动相互作用的实验数据,这种可能性还没有实现。有必要根据锥形毛细管的几何参数研究其对电子束的压缩情况,并研究聚焦过程的时间特征。在这项研究中,作者使用一个 15 毫米长、入口与出口内径比为 1.15 毫米/0.30 毫米的锥形玻璃通道,对 10 千伏电子束的压缩进行了实验研究。结果表明,在指定参数下,当通道轴线与初始电子束轴线平行时,毛细管出口处的电子束电流密度最多可增加 2.7 倍。据估计,这种密度的增加是针对初始能量损失不超过 1 千伏的电子而言的。研究还表明,无论毛细管相对于初始光束的方向如何,电子通过锥形毛细管传输的过程都是稳定的。
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Study of the Possibility of a Stable Increase in the Electron Beam Current Density Using a Tapered Glass Channel

The possibility of increasing the current density of a charged particle beam (focusing) by means of tapered glass channels without the use of external energy sources is actively translated into action today for positively charged ions. For electron beams, this possibility is not realized due to the lack of experimental data on the sliding interaction between electron beams and a dielectric surface. It is necessary to examine the compression of an electron beam by tapered capillaries depending on their geometrical parameters, as well as to study the temporal characteristics of the focusing process. In this work, the authors experimentally studied the compression of a 10 keV electron beam using a 15-mm-long tapered glass channel with an inlet-to-outlet inside diameter ratio of 1.15 mm/0.30 mm. The beam current density is shown to increase at the outlet of the capillary with the specified parameters by up to a factor of 2.7 for the position where the channel axis is parallel to that of the initial beam. This density increase is estimated for electrons that have lost no more than 1 keV of initial energy. It is also shown that the process of electron transmission by a tapered capillary is stable regardless of the orientation of the capillary with respect to the direction of the initial beam.

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来源期刊
Glass and Ceramics
Glass and Ceramics 工程技术-材料科学:硅酸盐
CiteScore
1.00
自引率
16.70%
发文量
85
审稿时长
6-12 weeks
期刊介绍: Glass and Ceramics reports on advances in basic and applied research and plant production techniques in glass and ceramics. The journal''s broad coverage includes developments in the areas of silicate chemistry, mineralogy and metallurgy, crystal chemistry, solid state reactions, raw materials, phase equilibria, reaction kinetics, physicochemical analysis, physics of dielectrics, and refractories, among others.
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