A construction method of the quasi-monolithic compact interferometer based on UV-adhesives bonding

Abstract

Quasi-monolithic interferometers play a crucial role in high-precision measurement experiments, including gravitational wave detection, inertial sensing, vibrometry, and seismology. Achieving high stability and accuracy in such interferometers requires a method for bonding optical components to a baseplate. While optical contact bonding and silicate bonding are common methods, UV adhesives offer advantages such as controlled curing and low geometrical requirements for optical components and baseplates. This paper presents a detailed construction method for a quasi-monolithic compact interferometer based on UV-adhesive bonding. We built two types of interferometers using this method: a 100\, mm × 100\, mm× 20\, mm Mach-Zender homodyne interferometer with unequal arm lengths of about 100\, mm for laser frequency noise monitoring, and a heterodyne interferometer as a displacement sensing head sizing 20\, mm × 30\, mm× 20\, mm. Our Mach-Zender interferometer achieved a phase noise level of 2\,μ rad Hz at 1\, Hz and a equivalent laser frequency noise monitoring sensitivity of about 1\, kHz/ Hz at 1\, Hz. The compact heterodyne interferometer sensing head showed a sensitivity level of 1\, pm/ Hz in translation and 0.2\, nrad/ Hz in two tilts above 0.4\, Hz. Our tests demonstrate that quasi-monolithic compact interferometers based on UV-adhesive bonding can achieve high sensitivity levels at the pico-meter and nano-radian scales.