Abstract
The demand for greenhouse gas measurement has increased dramatically due to global warming. A 1.57-μm airborne double-pulse integrated-path differential absorption (IPDA) light detection and ranging (LIDAR) system for CO2 concentration measurement was developed. The airborne field experiments of this IPDA LIDAR system were conducted at a flight altitude of approximately 7 km, and the weak echo signal of the ocean area was successfully received. The matched filter algorithm was applied to the retrieval of the weak signals, and the pulse integration method was used to improve the signal-to-noise ratio. The inversion results of the CO2 column-averaged dry-air mixing ratio (XCO2) by the scheme of averaging after log (AVD) and the scheme of averaging signals before log were compared. The AVD method was found more effective for the experiment. The long-term correlation between the changing trends of XCO2 retrieved by the IPDA LIDAR system and CO2 dry-air volume mixing ratio measured by the in-situ instrument reached 92%. In the steady stage of the open area (30 km away from the coast), which is almost unaffected by the residential areas, the mean value of XCO2 retrieved by the IPDA LIDAR system was 414.69 ppm, with the standard deviation being 1.02 ppm. Compared with the CO2 concentration measured by the in-situ instrument in the same period, bias was 1.30 ppm. The flight path passed across the ocean, residential, and mountainous areas, with the mean value of XCO2 of the three areas being 419.35, 429.29, and 422.52 ppm, respectively. The gradient of the residential and ocean areas was 9.94 ppm, with that of the residential and mountainous areas being 6.77 ppm. Obvious gradients were found in different regions.
Highlights
Atmospheric CO2 is an important greenhouse gas (GHG) that has increased rapidly in recent years due to human activities
The results showed that the 2-μm integrated path differential absorption (IPDA) light detection and ranging (LIDAR) system provided an accurate measurement with 0.36% difference at an average range of 10 s compared with the CO2 mixing ratio measured by National Oceanic and Atmospheric Administration (NOAA) flask sampling data
The 1.57-μm airborne double-pulse IPDA LIDAR system is developed for CO2 measurement
Summary
Atmospheric CO2 is an important greenhouse gas (GHG) that has increased rapidly in recent years due to human activities. NASA Langley Research Center has developed a double-pulse, 2-μm IPDA LIDAR instrument for atmospheric CO2 measurement [7,13]. In 2014, the airborne operation was conducted, and the experiment results were reported by Yu et al [7,13]. NASA Goddard Space Flight Center has developed a pulsed IPDA LIDAR system that uses a multiple-wavelength-locked laser and HgCdTe APD detector for XCO2 measurements during airborne experiments [10]. We present a new 1.57-μm airborne double-pulse IPDA LIDAR system with an InGaAs APD detector and airborne experiment for the measurement of atmospheric CO2. Using the recorded real-time wavelength for data inversion can reduce the error of inversion result caused by laser frequency drift. TThheereresusultlstsaraeredidscisucsusessdeidn iSnecSteiocntio5n, a5n,datnhde mthoesmt imospt oimrtapnotrfitanndtinfignsdoinf gthsisosfttuhdisy satruedcyonacrelucdoendcliundSeedctiinonSe6c.tion 6
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