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Quantum gravimetry with mechanical qubits

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abstract

Levitated mesoscopic particles hold the promise of revolutionizing gravity sensing by using quantum effects. However, conventional quantum gravimeters based on such systems fail to harness the intrinsic large-mass advantage of the particles, because their commonly utilized auxiliary quantum systems counteract the role of mass as a resource. To overcome this limitation, we propose a quantum gravimetry by directly using the mechanical qubit (QM) formed by a levitated particle as the gravity sensor. Without resorting to the auxiliary quantum system, our scheme enables a straightforward readout of the particle's motion under gravitational influence. The obtained sensitivity behaves as a $m^{-1/2}$-scaling with the mass $m$. We also generalize our scheme to the \textit{mechanical cat qubit} as the gravity sensor. The sensitivity further scales as $N^{-1/2}$ with the mean phonon number $N$. In the experimentally realizable parameter regime, a sensitivity on the order of $0.1~ \text{\textmu}\text{Gal}/\sqrt{\text{Hz}}$ can be achieved, which outperforms the traditional schemes by two orders of magnitude. Reaching the \textit{double standard quantum limits} with $m$ and $N$ simultaneously, our scheme provides a feasible route toward compact high-sensitivity quantum gravimetry.

fields

quant-ph 1

years

2026 1

verdicts

UNVERDICTED 1

representative citing papers

Mechanical Squeezed-Fock Gravimeter

quant-ph · 2026-05-27 · unverdicted · novelty 7.0

A mechanical squeezed-Fock qubit gravimeter is proposed in which squeezing enhances gravity-induced transitions in a Duffing oscillator while converting dissipation into anisotropic noise.

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  • Mechanical Squeezed-Fock Gravimeter quant-ph · 2026-05-27 · unverdicted · none · ref 24 · internal anchor

    A mechanical squeezed-Fock qubit gravimeter is proposed in which squeezing enhances gravity-induced transitions in a Duffing oscillator while converting dissipation into anisotropic noise.