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Coherently parallel fiber-optic distributed acoustic sensing using dual Kerr soliton microcombs

Jian-Ting Li, Bing Chang, Junting Du, Teng Tan, Yong Geng, Heng Zhou, Yupei Liang, Hao Zhang, Guofeng Yan, Lingmei Ma, Zengling Ran, Zinan Wang, Baicheng Yao, Yunjiang Rao

2024Science Advances89 citationsDOIOpen Access PDF

Abstract

Fiber-optic distributed acoustic sensing (DAS) has proven to be a revolutionary technology for the detection of seismic and acoustic waves with ultralarge scale and ultrahigh sensitivity, and is widely used in oil/gas industry and intrusion monitoring. Nowadays, the single-frequency laser source in DAS becomes one of the bottlenecks limiting its advance. Here, we report a dual-comb-based coherently parallel DAS concept, enabling linear superposition of sensing signals scaling with the comb-line number to result in unprecedented sensitivity enhancement, straightforward fading suppression, and high-power Brillouin-free transmission that can extend the detection distance considerably. Leveraging 10-line comb pairs, a world-class detection limit of 560 fε/√Hz@1 kHz with 5 m spatial resolution is achieved. Such a combination of dual-comb metrology and DAS technology may open an era of extremely sensitive DAS at the fε/√Hz level, leading to the creation of next-generation distributed geophones and sonars.

Topics & Concepts

Distributed acoustic sensingSensitivity (control systems)InterferometryOptical fiberOpticsTransmission (telecommunications)Superposition principleComputer scienceAcousticsPhysicsFiber optic sensorTelecommunicationsElectronic engineeringEngineeringQuantum mechanicsAdvanced Fiber Laser TechnologiesAdvanced Fiber Optic SensorsPhotonic and Optical Devices
Coherently parallel fiber-optic distributed acoustic sensing using dual Kerr soliton microcombs | Litcius