Electron Beam Loss Monitor of Areal Accelerator Based on Pin-Photodiodes

IF 0.5 4区物理与天体物理 Q4 PHYSICS, MULTIDISCIPLINARY Journal of Contemporary Physics (Armenian Academy of Sciences) Pub Date : 2023-06-18 DOI:10.1134/S1068337223010061

S. G. Arutyunyan, A. V. Margaryan, E. G. Lazareva, M. Chung, G. V. Mirzoyan, N. S. Mesropyan, V. G. Khachatryan, A. D. Davtyan

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Abstract

A prototype PIN-photodiode-based electron system for flux measurement of the AREAL accelerator electron beam (energy up to 5 MeV) was developed and tested. The system can be eventually used to measure beam losses from the vacuum chamber of the SASE100 undulator, which is intended for the generation of radiation in the terahertz range and will be installed in the AREAL accelerator tract during its modernization. The method of using the PIN-photodiodes as a beam loss monitor is based on the effect of electron–hole pairs formation when ionizing particles pass through the photodiode barrier layer. Calculations of the interaction of electrons with the substance of the barrier layer are performed using the PCLab program. The experiments carried out on the accelerator electron beam showed that the developed system can effectively register the electron fluxes of both the main beam of the AREAL accelerator and its dark current.

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基于pin -光电二极管的面加速器电子束损耗监测

研制并测试了一种用于测量区域加速器电子束(能量高达5 MeV)通量的pin -光电二极管电子系统原型。该系统最终可用于测量SASE100波动器真空室的光束损耗，该波动器用于产生太赫兹范围的辐射，并将在其现代化期间安装在AREAL加速器通道中。利用pin -光电二极管作为束流损耗监测仪的方法是基于电离粒子穿过光电二极管势垒层时电子-空穴对形成的影响。利用PCLab程序计算了电子与势垒层物质的相互作用。在加速器电子束上进行的实验表明，所开发的系统可以有效地记录AREAL加速器主束和暗电流的电子通量。

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来源期刊

Journal of Contemporary Physics (Armenian Academy of Sciences) PHYSICS, MULTIDISCIPLINARY-

CiteScore

1.00

自引率

66.70%

发文量

审稿时长

6-12 weeks

期刊介绍： Journal of Contemporary Physics (Armenian Academy of Sciences) is a journal that covers all fields of modern physics. It publishes significant contributions in such areas of theoretical and applied science as interaction of elementary particles at superhigh energies, elementary particle physics, charged particle interactions with matter, physics of semiconductors and semiconductor devices, physics of condensed matter, radiophysics and radioelectronics, optics and quantum electronics, quantum size effects, nanophysics, sensorics, and superconductivity.