分类: 物理学 >> 核物理学 提交时间: 2025-05-02
Qiu, Dr. F
Xu, Mr. Chengye
Zeng, Prof. Rihua
He, Prof. Yuan 何源
Wei, Miss Shihui
Peng, Mr. Jiayi
Yang, Dr. Lijuan
Yang, Prof. Ziqin
Zhang, Mr. Zhouli
Wang, Dr. Zhi-Jun
Wang, Dr. Muyuan
Maiano, Dr. Cecilia
Pierini, Dr. Paolo
摘要: Accurate calibration of the beam phase (the phase of the beam arrival relative to the cavity accelerating field) is essential for maintaining the stability and efficiency of linear accelerators. Conventional offline phase-scan methods, typically performed during commissioning or maintenance, require considerable manual effort and can disrupt regular operation. Moreover, these methods cannot effectively track gradual drifts caused by ambient conditions. An online beam-phase calibration technique using beam-induced radio-frequency (RF) transients was initially developed at DESY for superconducting cavities operating under open-loop conditions. Extending DESY's method to normal-conducting cavities at the European Spallation Source (ESS) introduces challenges. When the beam pulse length approaches the cavity time constant \( \tau = 1/\omega_{0.5} \), where \( \omega_{0.5} \) is the cavity half-bandwidth, detuning effects distort the trajectory of the beam-induced RF transient and degrade the beam phase measurement accuracy. Furthermore, open-loop operation is generally not advisable for high-current proton linacs because of stability and safety concerns. To address these issues, we revisited the cavity differential equations and proposed a detuning compensation method that corrects the distorted trajectory in the in-phase/quadrature plane. In addition, by analyzing the initial 1.4~\(\mu\)s transient response before low-level RF (LLRF) feedback becomes active, beam phase calibration can be achieved under closed-loop operation. Experimental results indicate that the proposed method agrees well with beam position monitor (BPM)-based measurements. This approach enables real-time beam phase monitoring without interrupting closed-loop operation and can be adapted to similar accelerator systems.
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