Study of Magnetic Hysteresis Effects in a Storage Ring Using Precision Tune Measurement

TL;DR

This paper investigates magnetic hysteresis effects in a storage ring, using precision tune measurements to understand their impact on beam energy and focusing, and develops methods for improved control and reproducibility.

Contribution

It provides experimental analysis of hysteresis effects in a storage ring and introduces a new technique for precise quadrupole focusing recovery.

Findings

Hysteresis effects significantly affect lattice focusing and beam energy.

A new method improves quadrupole focusing stability after adjustments.

Procedures for lattice preparation enhance reproducibility.

Abstract

With advances in accelerator science and technology in the recent decades, the accelerator community has focused on the development of next-generation light sources, for example the diffraction-limited storage rings (DLSRs), which requires precision control of the electron beam energy and betatron tunes. This work is aimed at understanding magnet hysteresis effects on the electron beam energy and lattice focusing in the circular accelerators, and developing new methods to gain better control of these effects. In this paper, we will report our recent experimental study of the magnetic hysteresis effects and their impacts on the Duke storage ring lattice using the transverse feedback based precision tune measurement system. The major magnet hysteresis effects associated with magnet normalization and lattice ramping are carefully studied to determine an effective procedure for lattice preparation while maintaining a high degree of reproducibility of lattice focusing. The local hysteresis effects are also studied by measuring the betatron tune shifts resulted from adjusting the setting of a quadrupole. A new technique has been developed to precisely recover the focusing strength of the quadrupole by returning it to a proper setting to overcome the local hysteresis effect.