Non-geometric tilt-to-length coupling in precision interferometry: mechanisms and analytical descriptions

TL;DR

This paper analyzes non-geometric tilt-to-length coupling in precision interferometry, providing analytical descriptions and insights into how beam and detector geometry influence noise, aiding in the design of low-noise interferometric systems.

Contribution

It offers the first detailed analytical characterization of non-geometric TTL coupling effects from beam properties and detector geometry in interferometry.

Findings

Analytical expressions for non-geometric TTL coupling effects.

Identification of conditions where geometric and non-geometric TTL effects cancel.

Guidelines for minimizing TTL noise through design and alignment.

Abstract

This paper is the second in a set of two investigating tilt-to-length (TTL) coupling. TTL describes the cross-coupling of angular or translational jitter into an interferometric phase signal and is an important noise source in precision interferometers, including space gravitational wave detectors like LISA. We discussed in 10.1088/2040-8986/ac675e the TTL coupling effects originating from optical path length changes, i.e. geometric TTL coupling. Within this work, we focus on the wavefront and detector geometry dependent TTL coupling, called non-geometric TTL coupling, in the case of two interfering fundamental Gaussian beams. We characterise the coupling originating from the properties of the interfering beams, i.e. their absolute and relative angle at the detector, their relative offset and the individual beam parameters. Furthermore, we discuss the dependency of the TTL coupling on the geometry of the detecting photodiode. Wherever possible, we provide analytical expressions for the expected TTL coupling effects. We investigate the non-geometric coupling effects originating from beam walk due to the angular or translational jitter of a mirror or a receiving system. These effects are directly compared with the corresponding detected optical path length changes in 10.1088/2040-8986/ac675e. Both together provide the total interferometric readout. We discuss in which cases the geometric and non-geometric TTL effects cancel one-another. Additionally, we list linear TTL contributions that can be used to counteract other TTL effects. Altogether, our results provide key knowledge to minimise the total TTL coupling noise in experiments by design or realignment.