A centimeter-sized gas pressure sensor for high-vacuum measurements at cryogenic temperatures

Abstract

Gas pressure sensors based on nanomechanical membranes have recently demonstrated an ultra-wide ten-decade measurement range, a gas-type-independent response, and a self-calibrating operation with uncertainties of approximately 1\,\%. The readout relied on tabletop free-space laser interferometers. Here we present a centimeter-sized, portable implementation in which a square Si3N4 membrane is read out via a fiber-based laser interferometer. We perform pressure measurements between 5×10-5 and 10-1~mbar in a confined 0.7~L volume cooled to 78~K. Because no suitable commercial pressure sensor exists for direct cryogenic comparison, we benchmark our device against room-temperature commercial gauges connected to the cold volume through a pipe of limited conductance. The measured relationship between the two sensors is compared with models accounting for temperature- and pumping-induced pressure gradients within the measurement chamber. These models agree with the measurements to within <10\,\% for helium and <13\,\% for nitrogen. The achieved readout sensitivity of Sx = 8×10-14\,m/Hz theoretically enables resolving the thermal displacement noise spectrum of a trampoline membrane at atmospheric pressure, with a peak response of 48\,Sx (25\,Sx) at 295\,K (78\,K). Our results suggest that the previously achieved pressure measurement range of ten decades with trampoline membranes is compatible with fiber-based optical readout. This paves the way for widely applicable pressure sensors in the centimeter size range in cryogenic environments.