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Quartz-enhanced photoacoustic spectroscopic methane sensor system using a quartz tuning fork-embedded, double-pass and off-beam configuration

Lien Hu, Chuantao Zheng, Minghui Zhang, Dan Yao, Jie Zheng, Yù Zhang, Yiding Wang, Frank K. Tittel

2020Photoacoustics46 citationsDOIOpen Access PDF

Abstract

Development of a methane (CH4) sensor system was reported based on a novel quartz-tuning-fork (QTF)-embedded, double-pass, off-beam quartz-enhanced photoacoustic spectroscopy (DP-OB-QEPAS). A simplified and accurate numerical model was presented to optimize the DP-OB-QEPAS spectrophone and to enhance the detection sensitivity. A compact and fiber-coupled acoustic detection module (ADM) with a volume of 3 × 2×1 cm3 and a weight of 9.7 g was fabricated. A continuous-wave distributed feedback diode laser was used to target the CH4 absorption line at 6046.95 cm−1. With the combination of wavelength modulation spectroscopy (WMS) and second harmonic (2f) detection technique, the CH4 sensor system reveals a 1σ detection limit of 8.62 parts-per-million in volume (ppmv) for a 0.3 s averaging time with an optimized modulation depth of 0.26 cm−1. The proposed CH4 sensor shows a similar or even lower level in the normalized noise equivalent absorption coefficient (NNEA) (1.8 × 10−8 cm−1∙W/√Hz), compared to previously reported QEPAS-based CH4 sensors.

Topics & Concepts

Photoacoustic spectroscopyMaterials scienceDetection limitTuning forkWavelengthQuartzVolume (thermodynamics)OpticsMethaneAbsorption (acoustics)Time delay and integrationBeam (structure)SpectroscopyDiodeSensitivity (control systems)Absorption spectroscopyLaserOptoelectronicsAnalytical Chemistry (journal)AcousticsChemistryElectronic engineeringVibrationPhysicsChromatographyOrganic chemistryQuantum mechanicsComposite materialEngineeringSpectroscopy and Laser ApplicationsAtmospheric and Environmental Gas DynamicsAtmospheric Ozone and Climate