A Sub-5mW Evanescent Field Atom Guide with Nanofibers towards Guided Atom Interferometry with Membrane Waveguides

Great progress has been made in the field of quantum inertial sensors, from the laboratory to the real-world use, which will ultimately require sensor miniaturization and ruggedization for dynamic motion. However, lateral atomic movement with respect to the sensing axis limits inertial sensing, which inspires the atom guides to ensure transverse atomic confinement. Compared to a relatively large free-space optical mode, an evanescent field (EF) mode with an advantageously small mode area allows for stronger atom-light interactions and lower optical power requirements for the atom guides. We study EF atom guides in nanofibers and waveguides with traveling evanescent waves, rather than EF optical lattices with standing evanescent waves. Our preliminary demonstration of an EF atom guide takes place on a nanofiber using 685 nm and 937 nm lights, and we experimentally show that the atomic coherence of the EF atom guide (685/937 nm) is similar to the EF optical lattice. By replacing the 685 nm light with 793 nm light, we further demonstrate the sub-5mW EF atom guide (793/937 nm) on nanofibers and assess relative power reduction of 61$\%$ on nanofibers and 78$\%$ on membrane waveguides, compared to nanofibers (685/937 nm), for the same optical potential depth. Power reduction is beneficial for reducing total optical power requirements and improving heat dissipation in vacuum for atom guiding on chip-based membrane-photonic devices. To connect this work with EF-guided atom interferometry, we evaluate the viability and potential benefits of using the low-power light configuration on membrane waveguides, presenting fabricated linear and circular waveguides for future demonstrations. This is a promising step towards a chip-scale quantum inertial sensor array with reduced size, weight, and power.