Airborne Lidar Measurements of XCO2 in Synoptically Active Environment and Associated Comparisons With Numerical Simulations

Samantha Walley; Sandip Pal; Joel F Campbell; Jeremy Dobler; Emily Bell; Brad Weir; Sha Feng; Thomas Lauvaux; David Baker; Nathan Blume; Wayne Erxleben; Tai-Fang Fan; Bing Lin; Doug McGregor; Michael D Obland; Chris O'Dell; Kenneth J Davis

doi:10.1029/2021JD035664

Airborne Lidar Measurements of XCO₂ in Synoptically Active Environment and Associated Comparisons With Numerical Simulations

J Geophys Res Atmos. 2022 Aug 27;127(16):e2021JD035664. doi: 10.1029/2021JD035664. Epub 2022 Aug 17.

Authors

Samantha Walley¹, Sandip Pal¹, Joel F Campbell², Jeremy Dobler³, Emily Bell⁴, Brad Weir^{5

6}, Sha Feng^{7

8}, Thomas Lauvaux^{8

9}, David Baker⁴, Nathan Blume³, Wayne Erxleben¹⁰, Tai-Fang Fan¹¹, Bing Lin², Doug McGregor³, Michael D Obland², Chris O'Dell⁴, Kenneth J Davis^{7

12}

Affiliations

¹ Department of Geosciences Atmospheric Science Division Texas Tech University Lubbock TX USA.
² NASA Langley Research Center (LaRC) Hampton VA USA.
³ Spectral Sensor Solutions LLC Fort Wayne IN USA.
⁴ Colorado State University Fort Collins CO USA.
⁵ Universities Space Research Association Columbia MD USA.
⁶ NASA Goddard Space Flight Center Greenbelt MD USA.
⁷ Atmospheric Sciences and Global Change Division Pacific Northwest National Laboratory Richland WA USA.
⁸ Department of Meteorology and Atmospheric Science The Pennsylvania State University University Park PA USA.
⁹ LSCE - IPSL CEA Saclay Saclay France.
¹⁰ L3 Harris Technologies Melbourne FL USA.
¹¹ Science System and Application, Inc Hampton VA USA.
¹² Earth and Environmental Systems Institute The Pennsylvania State University University Park PA USA.

Abstract

Frontal boundaries have been shown to cause large changes in CO₂ mole-fractions, but clouds and the complex vertical structure of fronts make these gradients difficult to observe. It remains unclear how the column average CO₂ dry air mole-fraction (XCO₂) changes spatially across fronts, and how well airborne lidar observations, data assimilation systems, and numerical models without assimilation capture XCO₂ frontal contrasts (ΔXCO_2, i.e., warm minus cold sector average of XCO₂). We demonstrated the potential of airborne Multifunctional Fiber Laser Lidar (MFLL) measurements in heterogeneous weather conditions (i.e., frontal environment) to investigate the ΔXCO₂ during four seasonal field campaigns of the Atmospheric Carbon and Transport-America (ACT-America) mission. Most frontal cases in summer (winter) reveal higher (lower) XCO₂ in the warm (cold) sector than in the cold (warm) sector. During the transitional seasons (spring and fall), no clear signal in ΔXCO₂ was observed. Intercomparison among the MFLL, assimilated fields from NASA's Global Modeling and Assimilation Office (GMAO), and simulations from the Weather Research and Forecasting--Chemistry (WRF-Chem) showed that (a) all products had a similar sign of ΔXCO₂ though with different levels of agreement in ΔXCO₂ magnitudes among seasons; (b) ΔXCO₂ in summer decreases with altitude; and (c) significant challenges remain in observing and simulating XCO₂ frontal contrasts. A linear regression analyses between ΔXCO₂ for MFLL versus GMAO, and MFLL versus WRF-Chem for summer-2016 cases yielded a correlation coefficient of 0.95 and 0.88, respectively. The reported ΔXCO₂ variability among four seasons provide guidance to the spatial structures of XCO₂ transport errors in models and satellite measurements of XCO₂ in synoptically-active weather systems.

Keywords: airborne atmospheric measurements; cold front; column average CO2 dry air mole fraction; greenhouse gases; mid‐latitude cyclone.