Rotation Sensing via Josephson-frequency Splitting in a Toroidal Superfluid
Abstract
We show that a toroidal superfluid interrupted by n tunneling barriers realizes a compact Josephson gyroscope with an n-enhanced response to rotation. In the small-amplitude regime, we derive analytically the normal mode spectrum of the coupled population-phase oscillations. In the absence of rotation, pairs of modes are degenerate: a finite angular velocity Ω lifts this degeneracy through a Doppler shift, producing a frequency splitting that grows linearly with both Ω and n. Full numerical simulations confirm this prediction and reveal long-lived two-frequency beatings, in sharp contrast with the monochromatic Josephson oscillations of the nonrotating system. These beatings provide a direct rotation signal with estimation uncertainty scaling as ΔΩ n-3/2, while remaining robust against imperfections and dynamical excitations. These results identify multi-junction toroidal superfluids as scalable, micrometer-size rotation sensors compatible with current experimental platforms.
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