Single-Element Dual-Interferometer for Precision Inertial Sensing: Sub-picometer Structural Stability and Performance as a Reference for Laser Frequency Stabilization
Abstract
To reach sub-picometer sensitivity in the millihertz range, displacement sensors based on laser interferometry require suppression of laser-frequency noise by several orders of magnitude. Many optical frequency stabilization methods exist with varying levels of complexity, size, and performance. In this paper, we describe the performance of a compact Mach-Zehnder interferometer based on a monolithic optic. The setup consists of a commercial fiber injector, a custom-designed pentaprism used to split and recombine the laser beam, and two photoreceivers placed at the complementary output ports of the interferometer. The structural stability of the prism is transferred to the laser frequency via amplification, integration, and feedback of the balanced-detection signal, achieving a fractional frequency instability better than 6 parts in , corresponding to an interferometer pathlength stability better than m.
Cite
@article{arxiv.2310.01078,
title = {Single-Element Dual-Interferometer for Precision Inertial Sensing: Sub-picometer Structural Stability and Performance as a Reference for Laser Frequency Stabilization},
author = {Victor Huarcaya and Miguel Dovale Álvarez and Kohei Yamamoto and Yichao Yang and Stefano Gozzo and Pablo Martínez Cano and Moritz Mehmet and Juan José Esteban Delgado and Jianjun Jia and Gerhard Heinzel},
journal= {arXiv preprint arXiv:2310.01078},
year = {2023}
}
Comments
10 pages, 4 figures