Persistence of moist plumes from overshooting convection in the Asian monsoon anticyclone

Creators: Khaykin, Sergey M.; Moyer, Elizabeth; Krämer, Martina; Clouser, Benjamin; Bucci, Silvia; Legras, Bernard; Lykov, Alexey; Afchine, Armin; Cairo, Francesco; Formanyuk, Ivan; Mitev, Valentin; Matthey, Renaud; Rolf, Christian; Singer, Clare E.; Spelten, Nicole; Volkov, Vasiliy; Yushkov, Vladimir; Stroh, Fred

Abstract

The Asian monsoon anticyclone (AMA) represents one of the wettest regions in the lower stratosphere (LS) and is a key contributor to the global annual maximum in LS water vapour. While the AMA wet pool is linked with persistent convection in the region and horizontal confinement of the anticyclone, there remain ambiguities regarding the role of tropopause-overshooting convection in maintaining the regional LS water vapour maximum. This study tackles this issue using a unique set of observations from aboard the high-altitude M55-Geophysica aircraft deployed in Nepal in summer 2017 within the EU StratoClim project. We use a combination of airborne measurements (water vapour, ice water, water isotopes, cloud backscatter) together with ensemble trajectory modelling coupled with satellite observations to characterize the processes controlling water vapour and clouds in the confined lower stratosphere (CLS) of the AMA. Our analysis puts in evidence the dual role of overshooting convection, which may lead to hydration or dehydration depending on the synoptic-scale tropopause temperatures in the AMA. We show that all of the observed CLS water vapour enhancements are traceable to convective events within the AMA and furthermore bear an isotopic signature of the overshooting process. A surprising result is that the plumes of moist air with mixing ratios nearly twice the background level can persist for weeks whilst recirculating within the anticyclone, without being subject to irreversible dehydration through ice settling. Our findings highlight the importance of convection and recirculation within the AMA for the transport of water into the stratosphere.

Additional Information

© Author(s) 2022. This work is distributed under the Creative Commons Attribution 4.0 License. Received: 7 August 2021 – Discussion started: 31 August 2021 - Revised: 9 January 2022 – Accepted: 29 January 2022 – Published: 10 March 2022. We gratefully thank the StratoClim coordination team and the Myasishchev Design Bureau for successfully conducting the field campaign. Meteorological analysis data are provided by the European Centre for Medium-Range Weather Forecasts. ERA-5 trajectory computations are generated using Copernicus Climate Change Service information. We also thank the AERIS/ICARE Data and Services Center for providing access to the MSG1 and Himawari data as well as computer resources for the production of the cloud top product using the NWC SAF GEO-v2018.1 algorithm. Last but certainly not least, we sincerely thank the three anonymous referees for their constructive remarks. This research has been supported by the StratoClim project of the European Community's Seventh Framework Programme (FP7/2007–2013) under grant agreement no. 603557 and by the Agence Nationale de la Recherche TTL-Xing ANR-17-CE01-0015 projects. Author contributions. SMK performed the airborne and satellite data analysis and wrote the draft. EM and BC provided airborne water isotope data. SB and BL performed the trajectory calculation and geostationary satellite data analysis. AL, IF and VY provided airborne water vapour data. MK, AA, CR and NS provided airborne total water and ice particle size data. FC provided airborne particle backscatter in situ data. VM and RM provided airborne lidar data. VV provided airborne temperature data. EM, CES, BC, MK, CR, BL and FS provided useful comments and participated in the redaction of the paper. Data availability. The airborne data will be available from the HALO database at https://halo-db.pa.op.dlr.de/mission/101 (last access: 30 July 2021) (DLR, 2021). In the meantime they may be provided by the respective principal investigator upon request. TRACZILLA data are available upon request. MLS data are publicly available at http://disc.sci.gsfc.nasa.gov/Aura/data-holdings/MLS (last access: 28 February 2022; Lambert et al., 2015), GNSS-RO data at https://www.romsaf.org/product_archive.php (last access: 28 February 2022; EUMETSAT, 2022), CALIOP data at https://doi.org/10.5067/CALIOP/CALIPSO/LID_L1-STANDARD-V4-10 (NASA/LARC/SD/ASDC, 2016), and CATS data at https://doi.org/10.5067/ISS/CATS/L1B_N-M7.2-V3-00 (NASA/LARC/SD/ASDC, 2019). Video supplement. The animation showing the hourly evolution of back trajectories released at the B7 point of StratoClim Geophysica flight F7 is available at: https://doi.org/10.5281/zenodo.5168703 (Khaykin et al., 2021). The supplement related to this article is available online at: https://doi.org/10.5194/acp-22-3169-2022-supplement. This paper was edited by Corinna Hoose and reviewed by three anonymous referees.

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