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Enhanced Optical Fiber for Distributed Acoustic Sensing beyond the Limits of Rayleigh Backscattering

Paul S. Westbrook, Kenneth S. Feder, Tristan Kremp, Eric M. Monberg, Hongchao Wu, Benyuan Zhu, Lei Huang, Debra A. Simoff, Scott Shenk, Vincent A. Handerek, Mohammad Karimi, Anthony Nkansah, Alan Hoi Lun Yau

2020iScience60 citationsDOIOpen Access PDF

Abstract

We report on engineered fibers with enhanced optical backscattering that exceeds Rayleigh scattering limits by more than one order of magnitude. We measure attenuation less than 0.5 dB/km from 1,300 to 1,650 nm. By controlling the enhanced backscatter over a 1.5-km length, we compensate for this attenuation, resulting in a higher backscatter signal at the end of the fiber. We demonstrate that the scattering strength may be stabilized for operation at temperatures above 200°C for at least 3 weeks. We show that the deleterious signal distortion due to the Kerr nonlinearity is within 10% of standard fiber. We then report on the use of these fibers in distributed acoustic sensing (DAS) measurements. A significant increase in acoustic signal-to-noise ratio leads to the possibility of improved spatial resolution in the enhanced fiber DAS system.

Topics & Concepts

Backscatter (email)Rayleigh scatteringAttenuationDistributed acoustic sensingDistortion (music)Optical fiberOpticsSIGNAL (programming language)ScatteringMaterials scienceFiberAcousticsFiber optic sensorOptoelectronicsPhysicsTelecommunicationsComputer scienceComposite materialAmplifierProgramming languageCMOSWirelessAdvanced Fiber Optic SensorsSeismic Waves and AnalysisPhotonic and Optical Devices
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