Enhanced stratospheric water vapor over the summertime continental United States and the role of overshooting convection

Herman, R. L.; Ray, E. A.; Rosenlof, Karen H.; Bedka, Kristopher M.; Schwartz, M.; Read, W. G.; Troy, R. F.; Chin, K. B.; Christensen, L. E.; Fu, Dejian; Stachnik, R. A.; Bui, T. Paul; Dean‐Day, Jonathan M.

doi:10.5194/acp-17-6113-2017

Cited by 39 publications

(40 citation statements)

References 46 publications

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“…High-altitude aircraft has observed localized convective hydration (Anderson et al, 2012;Corti et al, 2008;Danielsen, 1993;Hanisco et al, 2007;Herman et al, 2017;Khaykin et al, 2009;Kley et al, 1982;Smith et al, 2017); however, our calculations show that these events contribute <1% to the global stratospheric water vapor budget. Even if we narrow the range of impact to the tropical lower stratosphere (less than 30°latitude) the impact is 1-2%, much smaller than the 5-10% tropical increase computed by S14 using MERRA reanalysis.…”

Section: Impact Of Convectionmentioning

confidence: 54%

“…Both convection and diabatic upwelling supply water vapor to the upper tropical troposphere and play a role in determining the altitude of the tropopause (Randel & Wu, ; Son & Lee, ; Thuburn & Craig, ; Zhou & Holton, ). Midlatitude aircraft measurements suggest that overshooting convection can also move water directly into the stratosphere bypassing dehydration by the cold trap (Anderson et al, ; Danielsen, ; Hanisco et al, ; Herman et al, ; Smith et al, ). Recent tropical aircraft measurements show tropical convective overshoots reaching into the lower stratosphere (Corti et al, ; Khaykin et al, ).…”

Section: Introductionmentioning

confidence: 99%

“…water directly into the stratosphere bypassing dehydration by the cold trap (Anderson et al, 2012;Danielsen, 1993;Hanisco et al, 2007;Herman et al, 2017;Smith et al, 2017). Recent tropical aircraft measurements show tropical convective overshoots reaching into the lower stratosphere (Corti et al, 2008;Khaykin et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

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Convective Hydration of the Upper Troposphere and Lower Stratosphere

et al. 2018

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We use our forward domain filling trajectory model to explore the impact of tropical convection on stratospheric water vapor (H2O) and tropical tropopause layer cloud fraction (TTLCF). Our model results are compared to winter 2008/2009 TTLCF derived from Cloud‐Aerosol Lidar with Orthogonal Polarization and lower stratospheric H2O observations from the Microwave Limb Sounder. Convection alters the in situ water vapor by driving the air toward ice saturation relative humidity. If the air is subsaturated, then convection hydrates the air through the evaporation of ice, but if the air is supersaturated, then convective ice crystals grow and precipitate, dehydrating the air. On average, there are a large number of both hydrating and dehydrating convective events in the upper troposphere, but hydrating events exceed dehydrating events. Explicitly adding convection produces a less than 2% increase in global stratospheric water vapor during the period analyzed here. Tropical tropopause temperature is the primary control of stratospheric water vapor, and unless convection extends above the tropopause, it has little direct impact. Less than 1% of the model parcels encounter convection above the analyzed cold‐point tropopause. Convection, on the other hand, has a large impact on TTLCF. The model TTLCF doubles when convection is included, and this sensitivity has implications for the future climate‐related changes, given that tropical convective frequency and convective altitudes may change.

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Section: Impact Of Convectionmentioning

confidence: 54%

Section: Introductionmentioning

confidence: 99%

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Convective Hydration of the Upper Troposphere and Lower Stratosphere

et al. 2018

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“…Previous work has shown that TTL water vapor variability is mainly controlled by TTL temperature variability (Mote et al, 1996;Holton and Gettelman, 2001;Fueglistaler et al, 2009). In particular, variations in the BDC and QBO play key roles (Fueglistaler and Haynes, 2005;Geller et al, 2002;Liang et al, 2011;Liess and Geller, 2012;Calvo et al, 2010;Randel et al, 2006;Dessler et al, 2013Dessler et al, , 2014Tao et al, 2015).…”

Section: Discussionmentioning

confidence: 99%

“…Air enters the stratosphere from the tropical troposphere mainly through the tropical tropopause layer (TTL, ∼ 15-18 km) (Sherwood and Dessler, 2000;Fueglistaler et al, 2009), which serves as a transition region between the troposphere and stratosphere. It is generally recognized that the coldest temperatures in the TTL act like a "cold trap" that provides primary control on the amount of water vapor entering the lower stratosphere (Mote et al, 1996;Holton and Gettelman, 2001). Large interannual variations of TTL water vapor have been observed and attributed to a set of physical processes that affect water vapor by varying TTL temperatures, such as the quasi-biennial oscillation (QBO) (Geller et al, 2002;Fueglistaler and Haynes, 2005;Liang et al, 2011;Liess and Geller, 2012;Randel and Jensen, 2013;Wang et al, 2015;Tao et al, 2015) and the Brewer-Dobson circulation (BDC) (Randel et al, 2006;Calvo et al, 2010;Dessler et al, 2013Dessler et al, , 2014Fueglistaler et al, 2014;Gilford et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Effects of convective ice evaporation on interannual variability of tropical tropopause layer water vapor

Dessler

2018

Atmos. Chem. Phys.

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Water vapor interannual variability in the tropical tropopause layer (TTL) is investigated using satellite observations and model simulations. We break down the influences of the Brewer-Dobson circulation (BDC), the quasibiennial oscillation (QBO), and the tropospheric temperature ( T ) on TTL water vapor as a function of latitude and longitude using a two-dimensional multivariate linear regression. This allows us to examine the spatial distribution of the impact of each process on TTL water vapor. In agreement with expectations, we find that the impacts from the BDC and QBO act on TTL water vapor by changing TTL temperature. For T , we find that TTL temperatures alone cannot explain the influence. We hypothesize a moistening role for the evaporation of convective ice from increased deep convection as the troposphere warms. Tests using a chemistryclimate model, the Goddard Earth Observing System Chemistry Climate Model (GEOSCCM), support this hypothesis.

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Impacts of tropical tropopause warming on the stratospheric water vapor

Xia

Huang

et al. 2019

Clim Dyn

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Enhanced stratospheric water vapor over the summertime continental United States and the role of overshooting convection

Cited by 39 publications

References 46 publications

Convective Hydration of the Upper Troposphere and Lower Stratosphere

Convective Hydration of the Upper Troposphere and Lower Stratosphere

Effects of convective ice evaporation on interannual variability of tropical tropopause layer water vapor

Impacts of tropical tropopause warming on the stratospheric water vapor

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