Membrane-based Optomechanical Accelerometry
Abstract
Optomechanical accelerometers promise quantum-limited readout, high detection bandwidth, self-calibration, and radiation pressure stabilization. We present a simple, scalable platform that enables these benefits with nano- sensitivity at acoustic frequencies, based on a pair of vertically integrated SiN membranes with different stiffnesses, forming an optical cavity. As a demonstration, we integrate an ultrahigh-Q (), millimeter-scale SiN trampoline membrane above an unpatterned membrane on the same Si chip, forming a finesse cavity. Using direct photodetection in transmission, we resolve the relative displacement of the membranes with a shot-noise-limited imprecision of 7 fm/, yielding a thermal-noise-limited acceleration sensitivity of 562 n over a 1 kHz bandwidth centered on the fundamental trampoline resonance (40 kHz). To illustrate the advantage of radiation pressure stabilization, we cold damp the trampoline to an effective temperature of 4 mK and leverage the reduced energy variance to resolve an applied stochastic acceleration of 50 n in an integration time of minutes. In the future, we envision a small-scale array of these devices operating in a cryostat to search for fundamental weak forces such as dark matter.
Cite
@article{arxiv.2208.14984,
title = {Membrane-based Optomechanical Accelerometry},
author = {Mitul Dey Chowdhury and Aman R. Agrawal and Dalziel J. Wilson},
journal= {arXiv preprint arXiv:2208.14984},
year = {2022}
}