Extreme Outliers in Lower Stratospheric Water Vapor Over North America Observed by MLS: Relation to Overshooting Convection Diagnosed From Colocated Aqua‐MODIS Data

Werner, Frank; Schwartz, M.; Livesey, N. J.; Read, W. G.; Santee, M. L.

doi:10.1029/2020gl090131

Cited by 21 publications

(12 citation statements)

References 47 publications

(58 reference statements)

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“…Their convective overshooting origin is unambiguously supported by both the enhanced isotopic ratios in the moist plumes and by their traceability to convective events. Notably, the occurrence of lower stratospheric moist plumes above the monsoon regions is also supported by satellite observations (Fu et al, 2006;Schwartz et al, 2013;Werner et al, 2020), whereas the enhanced water isotopic ratios observed over these regions (Hanisco et al, 2007;Randel et al, 2012) support the role of overshooting convection in maintaining the water vapour maximum in the summer monsoon anticyclones. This process adds to 455 the radiatively-driven slow ascent of wet air through the warm tropopause in the northern part of AMA.…”

mentioning

confidence: 55%

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

Khaykin

Moyer

Krämer³

et al. 2021

Preprint

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Abstract. The Asian Monsoon Anticyclone (AMA) represents the wettest region in the lower stratosphere (LS) and is the 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 onboard 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 modeling coupled with satellite observations to characterize the processes controlling water vapour and clouds in the confined lower stratosphere (CLS) of 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 AMA. We show that all of the observed CLS water vapour enhancements are traceable to convective events within 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 AMA for the transport of water into the stratosphere.

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confidence: 55%

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

Khaykin

Moyer

Krämer³

et al. 2021

Preprint

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“…Three natural pathways for direct injection of H 2 O into the stratosphere exist: overshooting convection, pyrocumulonimbus (pyroCb) storms, and volcanic eruptions. The previous stratospheric H 2 O record measured by MLS was 26.3 ppmv at 100 hPa associated with an overshooting convective event in August 2019 that spanned thousands of square kilometers and persisted for several hours (Werner et al, 2020). Two pyroCbs stand out in the MLS H 2 O record: the 2017 Pacific Northwest (Pumphrey et al, 2021) and the 2019/2020 Australian New Year's (Kablick et al, 2020;Khaykin et al, 2020;Schwartz et al, 2020) events.…”

Section: Unprecedented Stratospheric H 2 O Injectionmentioning

confidence: 86%

Hunga Tonga-Hunga Ha'apai Hydration of the Stratosphere

Millán¹,

Santee

Lambert

et al. 2022

Preprint

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not only injected ash into the stratosphere but also large amounts of water vapor, breaking all records for direct injection of water vapor, by a volcano or otherwise, in the satellite era. This is not surprising since the Hunga Tonga-Hunga Ha'apai caldera was formerly situated 150 m below sea level. The massive blast injected water vapor up to altitudes as high as 53 km. Using measurements from the Microwave Limb Sounder on NASA's Aura satellite, we estimate that the excess water vapor is equivalent to around 10% of the amount of water vapor typically residing in the stratosphere. Unlike previous strong eruptions, this event may not cool the surface, but rather it could potentially warm the surface due to the excess water vapor. MILLÁN ET AL.

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“…Three natural pathways for direct injection of H 2 O into the stratosphere exist: overshooting convection, pyrocumulonimbus (pyroCb) storms, and volcanic eruptions. The previous stratospheric H 2 O record measured by MLS was 26.3 ppmv at 100 hPa associated with an overshooting convective event in August 2019 that spanned thousands of square kilometers and persisted for several hours (Werner et al., 2020 ). Two pyroCbs stand out in the MLS H 2 O record: the 2017 Pacific Northwest (Pumphrey et al., 2021 ) and the 2019/2020 Australian New Year's (Kablick et al., 2020 ; Khaykin et al., 2020 ; Schwartz et al., 2020 ) events.…”

Section: Unprecedented Stratospheric H 2 O Injectionmentioning

confidence: 96%