Design of a nonlinear quasi-integrable lattice for resonance suppression at the University of Maryland Electron Ring

K. Ruisard
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引用次数: 7

Abstract

Conventional particle accelerators use linear focusing forces for transverse confinement. As a consequence of linearity, accelerating rings are sensitive to myriad resonances and instabilities. At high beam intensity, uncontrolled resonance-driven losses can deteriorate beam quality and cause damage or radio-activation in beam line components and surrounding areas. This is currently a major limitation of achievable current densities in state-of-the-art accelerators. Incorporating nonlinear focusing forces into machine design should provide immunity to resonances through nonlinear detuning of particle orbits from driving terms. A theory of nonlinear integrable beam optics is currently being investigated for use in accelerator rings. Such a system has potential to overcome the limits on achievable beam intensity. This dissertation presents a plan for implementing a proof-of-principle quasi-integrable octupole lattice at the University of Maryland Electron Ring (UMER). UMER is an accelerator platform that supports the study of high-intensity beam dynamics. In this dissertation, two designs are presented that differ in both complexity and strength of predicted effects. A configuration with a single, relatively long octupole magnet is expected to be more stabilizing than an arrangement of many short, distributed octupoles. Preparation for this experiment required the development and characterization of a low-intensity regime previously not operated at UMER. Additionally, required tolerances for the control of first and second order beam moments in the proposed experiments have been determined on the basis of simulated beam dynamics. In order to achieve these tolerances, a new method for improved orbit correction is developed. Finally, a study of resonance-driven losses in the linear UMER lattice is discussed.
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用于抑制马里兰大学电子环共振的非线性拟可积晶格设计
传统的粒子加速器使用线性聚焦力进行横向约束。由于线性,加速环对无数共振和不稳定性很敏感。在高光束强度下,不受控制的共振驱动损耗会使光束质量恶化,并导致光束线组件和周围区域的损坏或无线电激活。这是目前最先进的加速器实现电流密度的主要限制。将非线性聚焦力结合到机器设计中,可以通过驱动项的粒子轨道非线性失谐来提供对共振的免疫力。目前正在研究一种用于加速器环的非线性可积光束光学理论。这种系统有潜力克服可达到的光束强度的限制。本文提出了一种在马里兰大学电子环(UMER)上实现原理证明的拟可积八极晶格的方案。UMER是一个支持高强度光束动力学研究的加速器平台。在本文中,提出了两种不同的设计,在复杂性和预测效应的强度。一个单一的、相对较长的八极磁铁的结构比许多短的、分布的八极磁铁的结构更稳定。该实验的准备工作需要开发和表征以前未在UMER操作过的低强度体系。此外,在模拟梁动力学的基础上,确定了实验中控制一阶和二阶梁矩所需的公差。为了实现这些公差,提出了一种改进轨道校正的新方法。最后,讨论了线性UMER晶格中共振驱动损耗的研究。
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