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Broadband continuous-wave differential absorption lidar for atmospheric remote sensing of water vapor

Jiheng Yu, Yuan Cheng, Zheng Kong, Jiaming Song, Yupeng Chang, Kun Liu, Zhenfeng Gong, Liang Mei

2024Optics Express17 citationsDOIOpen Access PDF

Abstract

What we believe to be a novel low-cost broadband continuous-wave water vapor differential absorption lidar (CW-DIAL) technique has been proposed and implemented by combing the Scheimpflug principle and the differential absorption method. The broadband CW-DIAL technique utilizes an 830-nm high-power multimode laser diode with 3-W output power as a tunable light source and a CMOS image sensor tilted at 45° as the detector. A retrieval algorithm dedicated for the broadband CW-DIAL technique has been developed to obtain range-resolved water vapor concentration from the DIAL signal. Atmospheric remote sensing of water vapor has been carried out on a near-horizontal water vapor path to validate the performance of the broadband CW-DIAL system. The retrieved water vapor concentration showed a good consistency with those measured by an air quality monitoring station, with a correlation coefficient of 0.9669. The fitting error of the water vapor concentration is found to be less than 10%. Numerical simulation studies have revealed that the aerosol-induced error on the water vapor concentration is below 5% with a background water vapor concentration of 5 g/m 3 for most atmospheric conditions. The experimental results have successfully demonstrated the feasibility of the present broadband CW-DIAL technique for range-resolved water vapor remote sensing.

Topics & Concepts

DialWater vaporLidarMaterials scienceOpticsRemote sensingAttenuation coefficientAttenuationBroadbandAbsorption (acoustics)Environmental scienceMeteorologyPhysicsAcousticsGeologyAtmospheric and Environmental Gas DynamicsSpectroscopy and Laser ApplicationsAdvanced Optical Sensing Technologies
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