强聚焦离子通道和起伏器中电子束的极端辐射发射机制

arXiv - PHYS - Accelerator Physics Pub Date : 2024-08-30 DOI:arxiv-2409.00186

A. Frazzitta, M. Yadav, J. Mann, A. R. Rossi, J. B. Rosenzweig

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引用次数: 0

摘要

本文对起伏器和离子通道辐射进行了基本比较。这两种装置的传统理论都无法准确描述高 $k$ 和 $K/\gamma$ 量级，从而低估了粒子轨迹的振幅和周期。这可能会导致在离子柱等许多具有实际意义的装置中对辐射发射的错误估计。对等离子体密度和减压器强度表达式的重新定义使得对粒子行为的预测更加可靠，重现了两个装置中最接近的可能条件，并在广泛的$K/\gamma$值范围内正确匹配了预期的倍他子振荡幅度和波长。然后，就可以通过单粒子和光束动力学的数值模拟来解决两个装置光谱特征的差异。在本文中，我们概述了一个理论框架，并将其结果与适用于可能辐射源的设置的数值模拟结果进行了比较。

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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Extreme radiation emission regime for electron beams in strong focusing ion channels and undulators

A fundamental comparison between undulator and ion channel radiation is presented. Conventional theory for both devices fails to describe high $k$ and $K/\gamma$ regimes accurately, providing an underestimation of particle trajectory amplitude and period. This may lead to incorrect estimation of radiation emission in many setups of practical interest, such as the ion column. A redefinition of plasma density and undulator strength expressions leads to a more reliable prediction of particle behaviour, reproducing the closest possible conditions in the two devices and correctly matching expected betatron oscillation amplitude and wavelength for a wide range of $K/\gamma$ values. Differences in spectral features of the two devices can then be addressed via numerical simulations of single particle and beam dynamics. In this paper we outline a theoretical framework and compare its results with numerical simulation applied to setups eligible for possible radiation sources.

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arXiv - PHYS - Accelerator Physics

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