Researches on Non-standard Optics for Advanced Gravitational Waves Interferometers

TL;DR

This thesis investigates non-standard optical techniques, including mesa beams and coating optimization, to reduce thermal noise in advanced gravitational wave interferometers, aiming to enhance their sensitivity.

Contribution

It introduces a theoretical framework for mesa beams, develops new simulation tools, and demonstrates the potential of coating optimization to improve detector performance.

Findings

Analytical derivation of mesa beam parameters.

Prototype mesa beam Fabry-Perot cavity constructed and tested.

Coating thickness optimization reduces mirror thermal noise.

Abstract

This thesis presents a collection of different researches on non-standard optics in view of enhancing the performances of the Advanced Gravitational waves interferometric detectors, where the thermal noise of the test masses is expected to be a limiting factor for their sensitivity. We provide a quantitative analysis of the impact of non-Gaussian beams on different kinds of thermal noises. We developed the theory of mesa beam, in view of a future implementation in advanced GW interferometers of the mesa beam idea, focusing on the analytical derivation of the quantities (i.e. beam width, divergence, propagation factor), which are chosen as ISO standard reference parameters for the characterization of an optical beam. We also analytically proved a new duality relation between optical cavities with non-spherical mirrors. The interest of the GW community in this new beam technology led us to the construction and testing of a prototype mesa beam Fabry-Perot cavity with Mexican-hat mirror. Part of the work of this thesis was devoted to the development of new simulation programs of optical systems. These programs provided the theoretical expected behaviour of our experiment, in particular cavity modes structure and misalignments sensitivity to be confronted with the experimental results. We also explored another complementary way of reducing the mirror thermal noise, beside the beam shaping, that is the multi-layered coating thickness optimization. We show it to be effective in reducing the coating noise and explore the possible implications for GW interferometers in terms of sensitivity. During this analysis we developed an independent model for the coating effective elastic parameters, which is based on the well understood subject of homogenization theory.