Enhanced sensing of 3.4 GHz microwave in multi-level Rydberg atomic system

TL;DR

This paper demonstrates an enhanced Rydberg atomic sensor that improves the bandwidth and sensitivity of 3.4 GHz microwave detection through optimized quantum coherence and optical pumping techniques.

Contribution

It introduces a multi-level Rydberg atomic scheme with optimized coherence, significantly enhancing microwave sensing performance compared to traditional methods.

Findings

Enhanced quantum coherence improves EIT and AT splitting.

Sensitivity increased by 1.3 times through optimization.

Achieved 0.3 GHz bandwidth at 3.4 GHz detection.

Abstract

The Rydberg-based microwave detection is an all-optical technology that uses the strong coherent interaction between Rydberg atoms and microwave field. Different from the traditional microwave meter, the Rydberg atomic sensing is a new-type microwave detector that transforms the microwave spectrum into a coherent optical spectrum, and arouses increasingly the interests due to its high sensibility. For this kind of sensor, the coherence effect induced by coupling atoms with microwave plays a key role, and the decoherence may reduce the sensitivity. A multi-level Rydberg atomic scheme with optimized quantum coherence, which enhances both the bandwidth and the sensitivity for 4 GHz microwave sensing, is demonstrated experimentally in this work. The enhanced quantum coherence of Rydberg electromagnetically induced transparency (EIT) and microwave induced Autler-Townes (AT) splitting in EIT windows are shown using optical pumping at D1 line. The enhanced sensitivity at 3.4 GHz with 0.3 GHz bandwidth can be realized, based on the enhanced EIT-AT spectrum. The experimental results show that in the stepped Rydberg EIT system, the spectral width of EIT and microwave field EIT-AT can be narrowed by optical pumping (OP), so the sensitivity of microwave electric field measurement can be improved. After optimizing the EIT amplitude and adding single-frequency microwaves, the sensitivity of the microwave electric field measurement observed by the AT splitting interval is improved by 1.3 times. This work provides a reference for utilizing atomic microwave detection.