Observational constraints on the efficiency of dehydration mechanisms in the tropical tropopause layer

A. W. Rollins; T. D. Thornberry; R. S. Gao; S. Woods; R. P. Lawson; T. P. Bui; E. J. Jensen; D. W. Fahey

doi:10.1002/2016GL067972

Observational constraints on the efficiency of dehydration mechanisms in the tropical tropopause layer

A. W. Rollins, T. D. Thornberry, R. S. Gao, S. Woods, R. P. Lawson, T. P. Bui, E. J. Jensen, D. W. Fahey

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25 Scopus citations

Abstract

The efficiency of dehydration in the tropical tropopause layer (TTL) determines how closely water vapor will be reduced to the lowest saturation mixing ratio encountered along a trajectory to the stratosphere, thereby strongly influencing stratospheric humidity. The NASA Airborne Tropical Tropopause Experiment (ATTREX) provided an unprecedented number and quality of in situ observations to constrain the key mechanisms controlling this dehydration. Statistical analyses of the ATTREX data show that nucleation, growth, and sedimentation each result in TTL dehydration becoming increasingly inefficient at temperatures below 200 K. Because of these inefficiencies, models that ignore these mechanisms likely underestimate water vapor at the stratospheric entry point by ∼10-20% at the lowest temperatures.

Original language	English
Pages (from-to)	2912-2918
Number of pages	7
Journal	Geophysical Research Letters
Volume	43
Issue number	6
DOIs	https://doi.org/10.1002/2016GL067972
State	Published - Mar 28 2016

Keywords

cirrus
dehydration
stratospheric water vapor
TTL

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10.1002/2016GL067972

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title = "Observational constraints on the efficiency of dehydration mechanisms in the tropical tropopause layer",

abstract = "The efficiency of dehydration in the tropical tropopause layer (TTL) determines how closely water vapor will be reduced to the lowest saturation mixing ratio encountered along a trajectory to the stratosphere, thereby strongly influencing stratospheric humidity. The NASA Airborne Tropical Tropopause Experiment (ATTREX) provided an unprecedented number and quality of in situ observations to constrain the key mechanisms controlling this dehydration. Statistical analyses of the ATTREX data show that nucleation, growth, and sedimentation each result in TTL dehydration becoming increasingly inefficient at temperatures below 200 K. Because of these inefficiencies, models that ignore these mechanisms likely underestimate water vapor at the stratospheric entry point by ∼10-20\% at the lowest temperatures.",

keywords = "cirrus, dehydration, stratospheric water vapor, TTL",

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AU - Rollins, A. W.

AU - Thornberry, T. D.

AU - Gao, R. S.

AU - Woods, S.

AU - Lawson, R. P.

AU - Bui, T. P.

AU - Jensen, E. J.

AU - Fahey, D. W.

PY - 2016/3/28

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N2 - The efficiency of dehydration in the tropical tropopause layer (TTL) determines how closely water vapor will be reduced to the lowest saturation mixing ratio encountered along a trajectory to the stratosphere, thereby strongly influencing stratospheric humidity. The NASA Airborne Tropical Tropopause Experiment (ATTREX) provided an unprecedented number and quality of in situ observations to constrain the key mechanisms controlling this dehydration. Statistical analyses of the ATTREX data show that nucleation, growth, and sedimentation each result in TTL dehydration becoming increasingly inefficient at temperatures below 200 K. Because of these inefficiencies, models that ignore these mechanisms likely underestimate water vapor at the stratospheric entry point by ∼10-20% at the lowest temperatures.

AB - The efficiency of dehydration in the tropical tropopause layer (TTL) determines how closely water vapor will be reduced to the lowest saturation mixing ratio encountered along a trajectory to the stratosphere, thereby strongly influencing stratospheric humidity. The NASA Airborne Tropical Tropopause Experiment (ATTREX) provided an unprecedented number and quality of in situ observations to constrain the key mechanisms controlling this dehydration. Statistical analyses of the ATTREX data show that nucleation, growth, and sedimentation each result in TTL dehydration becoming increasingly inefficient at temperatures below 200 K. Because of these inefficiencies, models that ignore these mechanisms likely underestimate water vapor at the stratospheric entry point by ∼10-20% at the lowest temperatures.

KW - cirrus

KW - dehydration

KW - stratospheric water vapor

KW - TTL

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JO - Geophysical Research Letters

JF - Geophysical Research Letters

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Observational constraints on the efficiency of dehydration mechanisms in the tropical tropopause layer

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