Short circuit of water vapor and polluted air to the global stratosphere by convective transport over the Tibetan Plateau

doi:10.1073/pnas.0601584103

Short circuit of water vapor and polluted air to the global stratosphere by convective transport over the Tibetan Plateau

*School of Earth and Atmospheric Sciences, Georgia Institute of Technology, Atlanta, GA 30332-0340;
^‡Jet Propulsion Laboratory, California Institute of Technology, Pasadena, CA 91109; and
^§Institute of Atmospheric and Environmental Science, School of Geosciences, University of Edinburgh, EH9 3JN Edinburgh, United Kingdom

Contributed by Robert E. Dickinson, February 25, 2006

Abstract

During boreal summer, much of the water vapor and CO entering the global tropical stratosphere is transported over the Asian monsoon/Tibetan Plateau (TP) region. Studies have suggested that most of this transport is carried out either by tropical convection over the South Asian monsoon region or by extratropical convection over southern China. By using measurements from the newly available National Aeronautics and Space Administration Aura Microwave Limb Sounder, along with observations from the Aqua and Tropical Rainfall-Measuring Mission satellites, we establish that the TP provides the main pathway for cross-tropopause transport in this region. Tropospheric moist convection driven by elevated surface heating over the TP is deeper and detrains more water vapor, CO, and ice at the tropopause than over the monsoon area. Warmer tropopause temperatures and slower-falling, smaller cirrus cloud particles in less saturated ambient air at the tropopause also allow more water vapor to travel into the lower stratosphere over the TP, effectively short-circuiting the slower ascent of water vapor across the cold tropical tropopause over the monsoon area. Air that is high in water vapor and CO over the Asian monsoon/TP region enters the lower stratosphere primarily over the TP, and it is then transported toward the Asian monsoon area and disperses into the large-scale upward motion of the global stratospheric circulation. Thus, hydration of the global stratosphere could be especially sensitive to changes of convection over the TP.

Footnotes

^†To whom correspondence may be addressed. E-mail: fu{at}eas.gatech.eduor robted{at}eas.gatech.edu
Author contributions: R.F. designed research; Y.H., J.S.W., M.F., and W.G.R. performed research; Y.H., J.S.W., J.H.J., M.C., M.F., W.G.R., and D.L.W. analyzed data; and R.F., R.E.D., J.S.W., and J.W.W. wrote the paper.
Conflict of interest statement: No conflicts declared.
Abbreviations:

Abbreviations:

AIRS,

Atmospheric Infrared Sounder;

IWC,

ice-water content;

LS,

lower stratosphere;

MLS,

Microwave Limb Sounder;

MODIS,

Moderate-Resolution Imaging Spectroradiometer;

NASA,

National Aeronautics and Space Administration;

PR,

precipitation radar;

RH,

relative humidity;

TP,

Tibetan Plateau;

TRMM,

Tropical Rainfall Measuring Mission;

UT,

upper troposphere;

ppbv,

parts per billion by volume.