Resonant and random excitations on the proton beam in the Large Hadron Collider for active halo control with pulsed hollow electron lenses

M. Fitterer, G. Stancari, A. Valishev, S. Redaelli, D. Valuch
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引用次数: 8

Abstract

We present the results of numerical simulations and experimental studies about the effects of resonant and random excitations on proton losses, emittances, and beam distributions in the Large Hadron Collider (LHC). In addition to shedding light on complex nonlinear effects, these studies are applied to the design of hollow electron lenses (HEL) for active beam halo control. In the High-Luminosity Large Hadron Collider (HL-LHC), a considerable amount of energy will be stored in the beam tails. To control and clean the beam halo, the installation of two hollow electron lenses, one per beam, is being considered. In standard electron-lens operation, a proton bunch sees the same electron current at every revolution. Pulsed electron beam operation (i.e., different currents for different turns) is also considered, because it can widen the range of achievable halo removal rates. For an axially symmetric electron beam, only protons in the halo are excited. If a residual field is present at the location of the beam core, these particles are exposed to time-dependent transverse kicks and to noise. We discuss the numerical simulations and the experiments conducted in 2016 and 2017 at injection energy in the LHC. The excitation patterns were generated by the transverse feedback and damping system, which acted as a flexible source of dipole kicks. Proton beam losses, emittances, and transverse distributions were recorded as a function of excitation patterns and strengths. The resonant excitations induced rich dynamical effects and nontrivial changes of the beam distributions, which, to our knowledge, have not previously been observed and studied in this detail. We conclude with a discussion of the tolerable and achievable residual fields and proposals for further studies.
大型强子对撞机中质子束的共振和随机激励,用于脉冲空心电子透镜主动晕控制
本文介绍了大型强子对撞机(LHC)中共振和随机激励对质子损失、发射和束流分布影响的数值模拟和实验研究结果。除了揭示复杂的非线性效应外,这些研究还应用于设计用于主动光束晕控制的空心电子透镜(HEL)。在高亮度大型强子对撞机(HL-LHC)中,相当多的能量将被储存在束流尾部。为了控制和清洁光束光晕,正在考虑安装两个中空的电子透镜,每个光束一个。在标准的电子透镜操作中,质子束在每一次旋转中都能看到相同的电子电流。脉冲电子束操作(即,不同的电流为不同的匝数)也被考虑,因为它可以扩大可实现的光晕去除率的范围。对于轴对称电子束,只有晕中的质子被激发。如果在光束核心的位置存在残余场,这些粒子就会暴露于随时间变化的横向踢动和噪声中。我们讨论了2016年和2017年在大型强子对撞机中进行的数值模拟和实验。激励模式是由横向反馈和阻尼系统产生的,该系统作为偶极子踢的柔性源。质子束损耗、发射率和横向分布被记录为激发模式和强度的函数。共振激励引起了丰富的动力学效应和光束分布的重大变化,据我们所知,这在以前还没有被观察和研究过。最后,讨论了可容忍和可实现的残余场,并提出了进一步研究的建议。
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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