Olivia R. Green, Yiliang Bao, John R. Lawall, Jason J. Gorman, Daniel S. Barker
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Accurate, precise pressure sensing with tethered optomechanics
We show that optomechanical systems can be primary pressure sensors with
uncertainty as low as 1.1 % of reading via comparison with a pressure transfer
standard. Our silicon nitride and silicon carbide sensors are short-term and
long-term stable, displaying Allan deviations compatible with better than 1 %
precision and baseline drift significantly lower than the transfer standard. We
also investigate the performance of optomechanical devices as calibrated
gauges, finding that they can achieve total uncertainty less than 1 %. The
calibration procedure also yields the thin-film density of our sensors with
state-of-the-art precision, aiding development of other calibration-free
optomechanical sensors. Our results demonstrate that optomechanical pressure
sensors can achieve accuracy, precision, and drift sufficient to replace high
performance legacy gauges.
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