Linear electron accelerator for energy 8-50 MeV with injection from an electron source based on cluster plasma systems

IF 0.3 Q4 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS

Vestnik Sankt-Peterburgskogo Universiteta Seriya 10 Prikladnaya Matematika Informatika Protsessy Upravleniya Pub Date : 2022-01-01 DOI:10.21638/11401/spbu10.2022.403

I. Ashanin, Yulia D. Kluchevskaia, S. Polozov, V. Rashchikov

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引用次数: 0

Abstract

For many years, one of the key problems of modern accelerator physics has been an increase of the rate of the energy gain in RF linear electron accelerators. The physical limits of the accelerating field intensity for metallic accelerating structures have been practically reached; therefore, new acceleration schemes are being considered, primarily acceleration in plasma and wakefield acceleration. The second aim is the generation of ultrashort (100 fs and less) electron bunches, for which RF photoguns are traditionally used. In this case, for RF photoguns, a serious problem that limits the intensity of electrons in a bunch is the influence of the own space charge during emission and acceleration in the near-cathode region, where the beam is weakly relativistic and the influence of the space charge on its dynamics plays the determinative role. The possibility of using a plasma cathode source as an injector for RF accelerator will considered. In the future, this may make it possible to bypass the limitations inherent in RF photoguns (sufficient influence of the space charge on the beam dynamics in the near-cathode region) and acceleration in the laser-plasma channel (low electron capture coefficient in the acceleration mode, wide energy spectrum - 10% or more at energies of tens and hundreds of megaelectrons). It is proposed to develop a combined accelerator in which a bunch generated in a laser-plasma channel is injected into a traditional metal structure. It is supposed that could be possible to generate a short (from 0.1 to 1.0 ps) electron bunches with an energy of several hundred kiloelectrons, which will make it possible to consider such source as an alternative to the photocathode. Next, the beam must be captured in the acceleration mode in a normally conducting section and accelerated to an energy of 50 MeV with the possibility of energy tuning. The features of such accelerator, the features of the electron bunch capturing in the acceleration mode, and the possible values of the energy spectrum in such a system will considered.

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基于团簇等离子体系统的电子源注入能量为8-50 MeV的直线电子加速器

多年来，提高射频直线电子加速器的能量增益率一直是现代加速器物理学的关键问题之一。金属加速结构的加速场强的物理极限已经实际达到;因此，人们正在考虑新的加速方案，主要是等离子体加速和韦克菲尔德加速。第二个目标是产生超短(100秒或更短)电子束，这是传统上使用的射频光电枪。在这种情况下，对于射频光枪来说，限制束中电子强度的一个严重问题是在近阴极区域发射和加速过程中自身空间电荷的影响，在近阴极区域，光束是弱相对论性的，空间电荷对其动力学的影响起决定性作用。讨论了等离子体阴极源作为射频加速器注入器的可能性。在未来，这可能使绕过射频光电枪固有的限制(近阴极区域空间电荷对光束动力学的充分影响)和激光等离子体通道中的加速(加速模式中的低电子捕获系数，宽能谱-在数十和数百兆电子的能量下10%或更多)成为可能。提出了一种将激光等离子体通道中产生的束注入传统金属结构的组合加速器。据推测，有可能产生能量为几百千电子的短电子束(从0.1到1.0 ps)，这将使人们有可能考虑将这种源作为光电阴极的替代品。接下来，光束必须在正常传导部分以加速模式捕获，并加速到50兆电子伏的能量，并有可能进行能量调谐。讨论了该加速器的特性、加速模式下电子束捕获的特性以及该系统能谱的可能值。

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来源期刊

Vestnik Sankt-Peterburgskogo Universiteta Seriya 10 Prikladnaya Matematika Informatika Protsessy Upravleniya MATHEMATICS, INTERDISCIPLINARY APPLICATIONS-

CiteScore

1.30

自引率

50.00%

发文量

期刊介绍： The journal is the prime outlet for the findings of scientists from the Faculty of applied mathematics and control processes of St. Petersburg State University. It publishes original contributions in all areas of applied mathematics, computer science and control. Vestnik St. Petersburg University: Applied Mathematics. Computer Science. Control Processes features articles that cover the major areas of applied mathematics, computer science and control.