Weak interactions in ac-shaken ring lattices allow supercurrent-based atomtronic angular accelerometers to surpass the Fourier-limited sensitivity scaling of non-interacting atoms by over two orders of magnitude.
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UNVERDICTED 3representative citing papers
Resonance between on-site interactions and gravitational gradient in lattice BECs amplifies quantum Fisher information for gravimetry in the localized phase.
The chaotic phase of the tilted Bose-Hubbard model is identified via eigenstate structure and energy spectrum statistics as a function of energy, tilt strength, and interaction, with moderate tilt enhancing chaos and a phase diagram provided for homogeneous density setups.
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Enhancing supercurrent-based inertial sensing via interactions in atomtronic angular accelerometers
Weak interactions in ac-shaken ring lattices allow supercurrent-based atomtronic angular accelerometers to surpass the Fourier-limited sensitivity scaling of non-interacting atoms by over two orders of magnitude.
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Precision gravimetry via harnessing interaction-induced resonances in optical lattices
Resonance between on-site interactions and gravitational gradient in lattice BECs amplifies quantum Fisher information for gravimetry in the localized phase.
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Characterization of the chaotic phase in the tilted Bose-Hubbard model
The chaotic phase of the tilted Bose-Hubbard model is identified via eigenstate structure and energy spectrum statistics as a function of energy, tilt strength, and interaction, with moderate tilt enhancing chaos and a phase diagram provided for homogeneous density setups.