A Large Eddy Model Study on the Effect of Overshooting Convection on Lower Stratospheric Water Vapor

Using a cloud‐resolving large eddy model (LEM), we investigate how overshooting convection affects the water vapor content in the lower stratosphere. We design and conduct a series of sensitivity experiments to diagnose the effects of dynamical and thermodynamical background conditions on the transp...

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Bibliographic Details
Published in:Journal of geophysical research. Atmospheres 2018-09, Vol.123 (18), p.10,023-10,036
Main Authors: Sang, Wenjun, Huang, Qian, Tian, Wenshou, Wright, Jonathon S., Zhang, Jiankai, Tian, Hongying, Luo, Jiali, Hu, Dingzhu, Han, Yuanyuan
Format: Article
Language:English
Subjects:
Computer simulation
Convection
Geophysics
Gravitational waves
Gravity
gravity wave breaking
Gravity waves
Humidity
large eddy model
Lower stratosphere
Moisture content
overshooting convection
Parameterization
Sensitivity
Stratosphere
stratospheric water vapor
Sublimation
Tracking
Transport
Tropopause
Turbulent mixing
Turret
Vertical wind shear
Vortices
Water content
Water vapor
Water vapor content
Water vapor transport
Water vapour
Wave breaking
Wind
Wind shear
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Summary:Using a cloud‐resolving large eddy model (LEM), we investigate how overshooting convection affects the water vapor content in the lower stratosphere. We design and conduct a series of sensitivity experiments to diagnose the effects of dynamical and thermodynamical background conditions on the transport of water vapor into the lower stratosphere associated with overshooting convection. The three‐dimensional LEM simulations capture the bulk properties of the target case and track microphysical processes using a three‐phase microphysical parameterization. The model results indicate that the net effect of overshooting convection on lower stratospheric water content is moistening, primarily due to gravity wave breaking and ice sublimation. The contributions of small‐scale turbulent mixing to water vapor transport from the overshooting turret into the stratosphere are relatively weak. Sensitivity experiments show that convective intensity (as measured by updraft velocity) is directly related to the effect of overshooting convection on lower stratospheric humidity. This impact is quantified for the idealized target case. Changes in vertical wind shear near the tropopause have no significant impact on the extent of overshooting but have important impacts on cross‐tropopause water vapor exchange via their modulation of gravity wave breaking. Larger vertical wind shear in the tropopause layer inhibits the transport of water vapor and ice into the lower stratosphere by overshooting convection. Key Points Idealized simulations of overshooting tropical convection indicate net moistening of the lower stratosphere Stratospheric moistening results from ice sublimation and gravity wave breaking near the tropopause Effects of near‐tropopause vertical wind shear are mainly through modulation of gravity wave breaking rather than turbulent mixing
ISSN:2169-897X
2169-8996
DOI:10.1029/2017JD028069