Moisture-radiative cooling instability

Beucler, Tom; Cronin, Timothy W.

doi:10.1002/2016MS000763

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Moisture-radiative cooling instability

2016
By Beucler, Tom ; Cronin, Timothy W.
Source: Journal of Advances in Modeling Earth Systems 8(4), 1620-1640, 2016

[PDF-1.41 MB]

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Journal Title:

Journal of Advances in Modeling Earth Systems
Personal Author:

Beucler, Tom ; Cronin, Timothy W.

Beucler, Tom ; Cronin, Timothy W. Less -
NOAA Program & Office:

OAR (Oceanic and Atmospheric Research) ; CPO (Climate Program Office)

OAR (Oceanic and Atmospheric Research) ; CPO (Climate Program Office) Less -
Description:

Radiative-convective equilibrium (RCE)-the statistical equilibrium state of the atmosphere where convection and radiation interact in the absence of lateral transport-is widely used as a basic-state model of the tropical atmosphere. The possibility that RCE may be unstable to development of large-scale circulation has been raised by recent modeling, theoretical, and observational studies, and could have profound consequences for our understanding of tropical meteorology and climate. Here, we study the interaction between moisture and radiative cooling as a contributor to instability of RCE. We focus on whether the total atmospheric radiative cooling decreases with column water vapor; this condition, which we call moisture-radiative cooling instability (MRCI), provides the potential for unstable growth of moist or dry perturbations. Analytic solutions to the gray-gas radiative transfer equations show that MRCI is satisfied when the total column optical depth-linked to column water vapor-exceeds a critical threshold. Both the threshold and the growth rate of the instability depend strongly on the shape of the water vapor perturbation. Calculations with a realistic radiative transfer model confirm the existence of MRCI for typical tropical values of column water vapor, but show even stronger dependence on the vertical structure of water vapor perturbation. Finally, we analyze the sensitivity of atmospheric radiative cooling to variability in column water vapor in observed tropical soundings. We find that clear-sky MRCI is satisfied across a range of locations and seasons in the real tropical atmosphere, with a partial growth rate of similar to 1 month.
Keywords:

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Atmospheric Science Water Vapor, Atmospheric
Source:

Journal of Advances in Modeling Earth Systems 8(4), 1620-1640, 2016
DOI:

https://doi.org/10.1002/2016MS000763
Document Type:

Journal Article
Rights Information:

CC BY-NC-ND
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Submitted
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urn:sha256:e2ad22f0105d14af269c9cdf64229b8ac495764b9cc7523cfa3a1aec223fac63
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https://repository.library.noaa.gov/view/noaa/27882/noaa_27882_DS1.pdf
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Moisture-radiative cooling instability

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