Related papers: Quantum Weak Force Sensing with Squeezed Magnomechanics

Quantum Weak Force Sensing with Squeezed Magnomechanics

URL: http://arxiv.org/abs/2404.00723v1
Date: Sun, 31 Mar 2024 15:37:21 GMT
Title: Quantum Weak Force Sensing with Squeezed Magnomechanics
Authors: Qian Zhang, Jie Wang, Tian-Xiang Lu, Franco Nori, Hui Jing,
Abstract summary: We show that the performance of a quantum sensor can be significantly enhanced beyond the standard quantum limit by squeezing the magnons. Our findings provide a promising approach for highly tunable and compatible quantum force sensing using hybrid CMM devices.
Score: 4.183504602774295
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Cavity magnomechanics, exhibiting remarkable experimental tunability, rich magnonic nonlinearities, and compatibility with various quantum systems, has witnessed considerable advances in recent years. However, the potential benefits of using cavity magnomechanical (CMM) systems in further improving the performance of quantum-enhanced sensing for weak forces remain largely unexplored. Here we show that the performance of a quantum CMM sensor can be significantly enhanced beyond the standard quantum limit (SQL), by squeezing the magnons. We find that, for comparable parameters, two orders of enhancement in force sensitivity can be achieved in comparison with the case without the magnon squeezing. Moreover, we show optimal parameter regimes of homodyne angle for minimizing added quantum noise. Our findings provide a promising approach for highly tunable and compatible quantum force sensing using hybrid CMM devices, with potential applications ranging from quantum precision measurements to quantum information processing.

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