Trained correlated-photon illumination paired with a Transformer backend improves object classification accuracy by up to 15 percentage points in photon-starved noisy imaging.
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4 Pith papers cite this work. Polarity classification is still indexing.
years
2026 4verdicts
UNVERDICTED 4representative citing papers
Hot thermal states enable quantum-enhanced bosonic displacement sensing via parity projection and coherence mechanisms, making full ground-state cooling non-universal under realistic decoherence.
Proposes a protocol for preparing Fock and Schrödinger cat states in levitated particles via time-dependent modulation of weakly nonharmonic potentials combined with transient wave-function delocalization.
Direct use of mechanical qubits from levitated particles for gravimetry achieves m^{-1/2} sensitivity scaling and 0.1 μGal/√Hz performance, outperforming traditional schemes by two orders of magnitude while reaching double standard quantum limits.
citing papers explorer
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To Cool, or Not to Cool? Displacement Sensing with Hot Quantum States
Hot thermal states enable quantum-enhanced bosonic displacement sensing via parity projection and coherence mechanisms, making full ground-state cooling non-universal under realistic decoherence.
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Quantum Non-Gaussian State Preparation of Levitated Particles via Time-Dependent Control of Weakly Nonharmonic Hybrid Potentials
Proposes a protocol for preparing Fock and Schrödinger cat states in levitated particles via time-dependent modulation of weakly nonharmonic potentials combined with transient wave-function delocalization.
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Quantum gravimetry with mechanical qubits
Direct use of mechanical qubits from levitated particles for gravimetry achieves m^{-1/2} sensitivity scaling and 0.1 μGal/√Hz performance, outperforming traditional schemes by two orders of magnitude while reaching double standard quantum limits.