Litcius/Paper detail

Long-distance in-situ methane detection using near-infrared light-induced thermo-elastic spectroscopy

Lien Hu, Chuantao Zheng, Minghui Zhang, Kaiyuan Zheng, Jie Zheng, Zhanwei Song, Xiuying Li, Yù Zhang, Yiding Wang, Frank K. Tittel

2020Photoacoustics59 citationsDOIOpen Access PDF

Abstract

A wavelength-locked light-induced thermo-elastic spectroscopy (WL-LITES) gas sensor system was proposed for long-distance in-situ methane (CH4) detection using a fiber-coupled sensing probe. The wavelength-locked scheme was used to speed the sensor response without scanning the laser wavelength across the CH4 absorption line. A small-size piezoelectric quartz tuning fork (QTF) with a wide spectral response range was adopted to enhance the photo-thermal signal. The optical excitation parameters of the QTF were optimized based on experiment and simulation for improving the signal-to-noise ratio of the LITES technique. An Allan deviation analysis was employed to evaluate the limit of detection of the proposed sensor system. With a 0.3 s lock-in integration time and a ∼ 100 m optical fiber, the WL-LITES gas sensor system demonstrates a minimum detection limit (MDL) of ∼ 11 ppm in volume (ppmv) for CH4 detection, and the MDL can be further reduced to ∼ 1 ppmv with an averaging time of ∼ 35 s. A real-time in-situ monitoring of CH4 leakage reveals that the proposed sensor system can realize a fast response (< 12 s) for field application.

Topics & Concepts

Detection limitMaterials scienceAllan varianceWavelengthSpectroscopyOptical fiberPhotoacoustic spectroscopyOpticsSIGNAL (programming language)Time delay and integrationNear-infrared spectroscopyMethaneFiber optic sensorLaserDetection theorySignal-to-noise ratio (imaging)OptoelectronicsStandard deviationPhysicsChemistryDetectorComputer scienceProgramming languageChromatographyQuantum mechanicsOrganic chemistryStatisticsMathematicsSpectroscopy and Laser ApplicationsAdvanced Chemical Sensor TechnologiesAtmospheric Ozone and Climate