首次模拟 EuAPS Betatron 辐射源:专用辐射计算代码

Q3 Physics and Astronomy
Andrea Frazzitta, A. Bacci, Arianna Carbone, A. Cianchi, Alessandro Curcio, I. Drebot, M. Ferrario, V. Petrillo, Marcello Rossetti Conti, S. Samsam, L. Serafini, A. Rossi
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引用次数: 0

摘要

利用电子束的电子辐射发射产生x射线是许多研究领域的宝贵资源。EuPRAXIA先进光子源项目,在EuPRAXIA的框架内,旨在提供1-10 keV光子(x射线),开发一种紧凑的基于等离子体的系统,旨在利用高度非线性激光等离子体相互作用(LWFA)中发生的自注入过程来驱动电子β电子振荡。由于发射的辐射光谱、强度、角散度和可能的相干性在很大程度上取决于自注入光束的特性,因此需要对该过程进行准确的初步模拟,以评估最佳诊断设备规格并提供源性能的初步估计。已经为这些任务开发了一个专用工具;通过计算各种等离子体和激光参数组合的延迟场和谱,目前正在对粒子池(PIC)模拟的电子轨迹进行数值分析。对这些领域实施的前向方法评估可以允许将所提出的方案集成到已经存在的PIC代码中。因此,在检测器时间内进行光谱计算,给出线性复指数相位;这个特性允许半解析傅里叶变换的计算。给出了代码结构和一些轨迹分析结果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
First Simulations for the EuAPS Betatron Radiation Source: A Dedicated Radiation Calculation Code
X-ray production through betatron radiation emission from electron bunches is a valuable resource for several research fields. The EuAPS (EuPRAXIA Advanced Photon Sources) project, within the framework of EuPRAXIA, aims to provide 1–10 keV photons (X-rays), developing a compact plasma-based system designed to exploit self-injection processes that occur in the highly nonlinear laser-plasma interaction (LWFA) to drive electron betatron oscillations. Since the emitted radiation spectrum, intensity, angular divergence, and possible coherence strongly depend on the properties of the self-injected beam, accurate preliminary simulations of the process are necessary to evaluate the optimal diagnostic device specifications and to provide an initial estimate of the source’s performance. A dedicated tool for these tasks has been developed; electron trajectories from particle-in-cell (PIC) simulations are currently undergoing numerical analysis through the calculation of retarded fields and spectra for various plasma and laser parameter combinations. The implemented forward approach evaluation of the fields could allow for the integration of the presented scheme into already existing PIC codes. The spectrum calculation is thus performed in detector time, giving a linear complex exponential phase; this feature allows for a semi-analitical Fourier transform evaluation. The code structure and some trajectories analysis results are presented.
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来源期刊
Instruments
Instruments Physics and Astronomy-Instrumentation
CiteScore
2.60
自引率
0.00%
发文量
70
审稿时长
11 weeks
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