An optical tweezer implements state-dependent displacement, squeezing, rotation, and beamsplitter gates on the motional modes of trapped 40Ca+ ions.
Optimal Displacement Sensing with Spin-Dependent Squeezed States
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abstract
Displacement sensing is a fundamental task in metrology. However, the development of quantum-enhanced sensors that fully utilize the available degrees of freedom in many-body quantum systems remains an outstanding challenge. We propose many-body displacement sensing schemes that use spin-dependent squeezed (SDS) states -- hybrid spin-boson states whose bosonic squeezed quadrature is conditioned on an auxiliary spin. We prove that SDS states are \emph{optimal}, i.e. their quantum Cram\'{e}r-Rao bound saturates the Heisenberg limit. We propose explicit measurement sequences that can be readily implemented in systems such as trapped ions. We also introduce a scalable state-preparation protocol and numerically demonstrate the preparation of $8.7$~dB of spin-dependent squeezing $15$ times faster than the standard approach using second-order sidebands in trapped ions. The potential applications of our sensing protocols range from measuring single-photon scattering to searches for dark matter.
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quant-ph 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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State-dependent Gaussian gate set using an optical tweezer for trapped ions
An optical tweezer implements state-dependent displacement, squeezing, rotation, and beamsplitter gates on the motional modes of trapped 40Ca+ ions.