Concept Study of a Storage Ring-based Gravitational Wave Observatory: Gravitational Wave Strain and Synchrotron Radiation Noise

TL;DR

This paper explores the feasibility of detecting millihertz gravitational waves using a storage ring-based detector by analyzing the noise sources, especially synchrotron radiation, and proposes a design that could improve detection sensitivity.

Contribution

It introduces a novel concept for a storage ring-based gravitational wave detector and quantifies the noise limitations due to synchrotron radiation, providing a foundation for future experimental development.

Findings

Noise amplitude can be reduced below expected GW signals in the 10^{-4} - 10^{-2} Hz range.

Synchrotron radiation shot noise is a dominant limiting factor.

Design parameters like ion type and ring size influence detection sensitivity.

Abstract

This work for the first time addresses the feasibility of measuring millihertz gravitational waves (mHz GWs) with a storage ring-based detector. While this overall challenge consists of several partial problems, here we focus solely on quantifying design limitations imposed by the kinetic energy and radiated power of circulating ions at relativistic velocities. We propose an experiment based on the measurement of the time-of-flight signal of an ion chain. One of the dominant noise sources inherent to the measurement principle for such a GW detector is the shot noise of the emitted synchrotron radiation. We compute the noise amplitude of arrival time signals obtained by analytical estimates and simulations of ions with different masses and velocities circulating in a storage ring with the circumference of the Large Hadron Collider (LHC). Thereby, we show that our experiment design could reduce the noise amplitude due to the synchrotron radiation in the frequency range $10^{-4} - 10^{-2}$ Hz to one or two orders of magnitude below the expected GW signals from of astrophysical sources, such as super-massive binary black holes or extreme mass-ratio inspirals. Other key requirements for building a working storage ring-based GW detector include the generation and acceleration of heavy ion chains with the required energy resolution, their injection and continued storage, as well as the detection method to be used for the determination of the particle arrival time. However, these are not the focus of the work presented here, in which we instead concentrate on the definition of a working principle in terms of ion type, kinetic energy, and ring design, which will later serve as a starting point when addressing a more complete experimental setup.