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Main Authors: Suri, Nishchay, Wang, Zhihui, Roy, Tanay, Venturelli, Davide, de Jong, Wibe Albert
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.21983
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author Suri, Nishchay
Wang, Zhihui
Roy, Tanay
Venturelli, Davide
de Jong, Wibe Albert
author_facet Suri, Nishchay
Wang, Zhihui
Roy, Tanay
Venturelli, Davide
de Jong, Wibe Albert
contents We present a quantum sensing protocol for coupled qubit-oscillator systems that surpasses the standard quantum limit (SQL) by exploiting a geometrical phase. The signal is encoded in the geometrical phase that is proportional to the area enclosed in oscillator phase space. This area is amplified through squeezing, enabling sensitivities beyond the SQL. Our method is independent of oscillator's initial state, amenable to sensing with high-temperature or logical error-corrected states. The protocol shows robustness to qubit Markovian noise and preserves its state-independence, underscoring its practicality for next-generation quantum metrology. We demonstrate application to force sensing beyond the SQL in longitudinally coupled systems, and to high-precision measurements of couplings and pulse calibration surpassing SQL in dispersively coupled circuit quantum electrodynamics (cQED) architectures.
format Preprint
id arxiv_https___arxiv_org_abs_2511_21983
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Quantum Sensing using Geometrical Phase in Qubit-Oscillator Systems
Suri, Nishchay
Wang, Zhihui
Roy, Tanay
Venturelli, Davide
de Jong, Wibe Albert
Quantum Physics
We present a quantum sensing protocol for coupled qubit-oscillator systems that surpasses the standard quantum limit (SQL) by exploiting a geometrical phase. The signal is encoded in the geometrical phase that is proportional to the area enclosed in oscillator phase space. This area is amplified through squeezing, enabling sensitivities beyond the SQL. Our method is independent of oscillator's initial state, amenable to sensing with high-temperature or logical error-corrected states. The protocol shows robustness to qubit Markovian noise and preserves its state-independence, underscoring its practicality for next-generation quantum metrology. We demonstrate application to force sensing beyond the SQL in longitudinally coupled systems, and to high-precision measurements of couplings and pulse calibration surpassing SQL in dispersively coupled circuit quantum electrodynamics (cQED) architectures.
title Quantum Sensing using Geometrical Phase in Qubit-Oscillator Systems
topic Quantum Physics
url https://arxiv.org/abs/2511.21983