Related papers: Quantum Weak Measurement Amplifies Dispersion Signal of Rydberg Atomic System

Quantum Weak Measurement Amplifies Dispersion Signal of Rydberg Atomic System

URL: http://arxiv.org/abs/2503.03085v1
Date: Wed, 05 Mar 2025 00:54:44 GMT
Title: Quantum Weak Measurement Amplifies Dispersion Signal of Rydberg Atomic System
Authors: Yinghang Jiang, Jiguo Wu, Meng Shi, Hanqing Zheng, Fei Guo, Zhiguang Xiao, Zhiyou Zhang,
Abstract summary: This paper presents a scheme to amplify dispersion signal of Rydberg atomic microwave detection system.<n>The scheme effectively mitigates the impact of technical noise and can be used to achieve a measurement precision close to the limit set by atomic shot noise in theory.
Score: 1.2265940526918153
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Rydberg atoms, with their long coherence time and large electric dipole moment, are pivotal in quantum precision measurement. In the process of approaching the standard quantum limit, higher demands are placed on detection schemes. This paper presents a scheme to amplify dispersion signal of Rydberg atomic microwave detection system, using a quantum weak measurement technique together with improved dimensionless pointer. The scheme effectively mitigates the impact of technical noise and can be used to achieve a measurement precision close to the limit set by atomic shot noise in theory. Compared with the superheterodyne method based on transmission detection, our scheme has been experimentally proved to have a sensitivity increase of 5$\sim$6 dB. In this work, the Rydberg dispersion signal amplification mechanism offers a approach to enhance microwave detection sensitivity, which also facilitates deeper investigations into its dynamic processes and further applications of this mechanism in quantum communication and quantum control.

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