基于热离子枪的太赫兹自由电子激光器LINAC注入器的束流动力学设计

IF 4.4 2区物理与天体物理 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY

Results in Physics Pub Date : 2025-04-24 DOI:10.1016/j.rinp.2025.108266

Amin Ali Sadraei Javaheri , Fazel Jahangiri , Shahin Sanaye Hajari , Ali Reza Niknam

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引用次数: 0

摘要

太赫兹强辐射的广泛而多样的应用，促使世界各地的许多实验室都在开发基于快速发展的太赫兹自由电子激光技术的设备。这种系统的一个关键部件是它的直线加速器（直线加速器），它提供所需的高强度和高质量的电子束。作为核科学技术研究所高功率直线加速器（nstr - hpl）项目的一部分，太赫兹自由电子加速器的开发正在进行中。本文介绍了其电子注入器的束流动力学设计。基于国内能力，该系统由一个热电子电子枪、一个预集束器、一个长行波（TW）集束器和加速结构组成，可提供8 MeV能量的光束，脉冲电流高达1 a。为了得到较低发射度、束长和能量扩散的光束，已经采取了一些措施。这主要是聚束系统的责任。本文基于低梯度聚束的新概念，提出了一种特殊的行波聚束设计。得到的归一化光束发射度、束束长度和相对能量扩散分别为17.5 mm-mrad、8 ps和1.4%。最后，将该喷射器的性能与世界上一些现有的太赫兹自由电子激光器进行了比较。

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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Beam dynamics design of a thermionic gun-based LINAC injector for a THz-FEL oscillator

The broad and diverse applications of intense terahertz radiation have motivated many laboratories around the world in order to develop facilities based on the rapidly developing technology of terahertz free electron laser (THz-FEL). A key component of such a system is its linear accelerator (linac) that provides the required intense and high-quality electron beam. As a part of Nuclear Science and Technology Research Institute High Power Linac (NSTRI-HPL) project, the development of a THz-FEL is underway. This paper presents the beam dynamics design of its electron injector. Based on domestic capabilities, this system consists of a thermionic electron gun followed by a pre-buncher, a long Travelling Wave (TW) buncher and accelerating structures that provides a beam of 8 MeV energy with a pulse current up to 1 A. Cares has been taken in order to end up with a beam of lower emittance, bunch length and energy spread. This is mainly the responsibility of the bunching system. Here a special design of a travelling wave buncher has been presented based on the new concept of the low gradient bunching. The resulting normalized beam emittance, rms bunch length and the relative energy spread are 17.5 mm-mrad, 8 ps and 1.4 % respectively. At the end, the injector performance has been compared with some existing THz-FEL facilities worldwide.

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来源期刊

Results in Physics MATERIALS SCIENCE, MULTIDISCIPLINARYPHYSIC-PHYSICS, MULTIDISCIPLINARY

CiteScore

8.70

自引率

9.40%

发文量

754

审稿时长

50 days

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