Related papers: Quantum Advantage of One-Way Squeezing in Enhancing Weak-Force Sensing

Quantum Advantage of One-Way Squeezing in Enhancing Weak-Force Sensing

URL: http://arxiv.org/abs/2403.09979v1
Date: Fri, 15 Mar 2024 02:51:52 GMT
Title: Quantum Advantage of One-Way Squeezing in Enhancing Weak-Force Sensing
Authors: Jie Wang, Qian Zhang, Ya-Feng Jiao, Sheng-Dian Zhang, Tian-Xiang Lu, Zhipeng Li, Cheng-Wei Qiu, Hui Jing,
Abstract summary: We propose how to further improve the performance of quantum COM sensors by breaking reciprocal symmetry in purely quantum regime. We consider a spinning COM resonator and show that by selectively driving it in opposite directions, highly nonreciprocal optical squeezing can emerge. Our work confirms that breaking reciprocal symmetry, already achieved in diverse systems well beyond spinning systems, can serve as a new strategy to further enhance the abilities of advanced quantum sensors.
Score: 7.225053055214059
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Cavity optomechanical (COM) sensors, featuring efficient light-motion couplings, have been widely used for ultra sensitive measurements of various physical quantities ranging from displacements to accelerations or weak forces. Previous works, however, have mainly focused on reciprocal COM systems. Here, we propose how to further improve the performance of quantum COM sensors by breaking reciprocal symmetry in purely quantum regime. Specifically, we consider a spinning COM resonator and show that by selectively driving it in opposite directions, highly nonreciprocal optical squeezing can emerge, which in turn provides an efficient way to surpass the standard quantum limit that otherwise exists in conventional reciprocal devices. Our work confirms that breaking reciprocal symmetry, already achieved in diverse systems well beyond spinning systems, can serve as a new strategy to further enhance the abilities of advanced quantum sensors, for applications ranging from testing fundamental physical laws to practical quantum metrology.

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