Time Resolved Measurement of Electron Cloud Densities from Dispersion of Transverse Electric Pulses

TL;DR

This paper introduces a novel time-resolved microwave measurement technique for electron cloud densities in particle accelerators, using pulsed signals to achieve spatial and temporal mapping of cloud evolution.

Contribution

It proposes a new pulsed measurement method that enables time-resolved, localized electron cloud density measurements, improving upon previous average-based techniques.

Findings

Successful implementation of pulse-based measurement scheme

Ability to map electron cloud density at different points

Enhanced temporal resolution of electron cloud dynamics

Abstract

The measurement of electron cloud densities in particle accelerators using microwaves has proven to be an effective, non-invasive and inexpensive method. So far the experimental schemes have used continuous waves. This has either been in the form of travelling waves that are propagated, or standing waves that are trapped, in both cases within a segment of the accelerator chamber. The variation in the wave dispersion relation caused by the periodic creation and decay of the electron cloud leads to a phase modulation in the former case, and a frequency modulation in the latter. In general, these methods enable the measurement of a time averaged electron cloud density. In this paper we propose a time resolved measurement by using pulses propagated over a finite length of the accelerator chamber. The pulses are launched periodically, once after a bunch train has passed and then again half a revolution period later. This results in pulses alternating between a dispersion that is either affected by a cloud or not. The resulting spectrum of the signal can be related to the electron density sampled by the pulse that propagates through the cloud. By varying the delay of the launch of the pulse with respect to the train passage, one can map the cloud density at different points behind the train.