TY - JOUR
T1 - Process-evaluation of tropospheric humidity simulated by general circulation models using water vapor isotopic observations
T2 - 2. Using isotopic diagnostics to understand the mid and upper tropospheric moist bias in the tropics and subtropics
AU - Risi, Camille
AU - Noone, David
AU - Worden, John
AU - Frankenberg, Christian
AU - Stiller, Gabriele
AU - Kiefer, Michael
AU - Funke, Bernd
AU - Walker, Kaley
AU - Bernath, Peter
AU - Schneider, Matthias
AU - Bony, Sandrine
AU - Lee, Jeonghoon
AU - Brown, Derek
AU - Sturm, Christophe
PY - 2012
Y1 - 2012
N2 - Evaluating the representation of processes controlling tropical and subtropical tropospheric relative humidity (RH) in atmospheric general circulation models (GCMs) is crucial to assess the credibility of predicted climate changes. GCMs have long exhibited a moist bias in the tropical and subtropical mid and upper troposphere, which could be due to the mis-representation of cloud processes or of the large-scale circulation, or to excessive diffusion during water vapor transport. The goal of this study is to use observations of the water vapor isotopic ratio to understand the cause of this bias. We compare the three-dimensional distribution of the water vapor isotopic ratio measured from space and ground to that simulated by several versions of the isotopic GCM LMDZ. We show that the combined evaluation of RH and of the water vapor isotopic composition makes it possible to discriminate the most likely cause of RH biases. Models characterized either by an excessive vertical diffusion, an excessive convective detrainment or an underestimated in situ cloud condensation will all produce a moist bias in the free troposphere. However, only an excessive vertical diffusion can lead to a reversed seasonality of the free tropospheric isotopic composition in the subtropics compared to observations. Comparing seven isotopic GCMs suggests that the moist bias found in many GCMs in the mid and upper troposphere most frequently results from an excessive diffusion during vertical water vapor transport. This study demonstrates the added value of water vapor isotopic measurements for interpreting shortcomings in the simulation of RH by climate models.
AB - Evaluating the representation of processes controlling tropical and subtropical tropospheric relative humidity (RH) in atmospheric general circulation models (GCMs) is crucial to assess the credibility of predicted climate changes. GCMs have long exhibited a moist bias in the tropical and subtropical mid and upper troposphere, which could be due to the mis-representation of cloud processes or of the large-scale circulation, or to excessive diffusion during water vapor transport. The goal of this study is to use observations of the water vapor isotopic ratio to understand the cause of this bias. We compare the three-dimensional distribution of the water vapor isotopic ratio measured from space and ground to that simulated by several versions of the isotopic GCM LMDZ. We show that the combined evaluation of RH and of the water vapor isotopic composition makes it possible to discriminate the most likely cause of RH biases. Models characterized either by an excessive vertical diffusion, an excessive convective detrainment or an underestimated in situ cloud condensation will all produce a moist bias in the free troposphere. However, only an excessive vertical diffusion can lead to a reversed seasonality of the free tropospheric isotopic composition in the subtropics compared to observations. Comparing seven isotopic GCMs suggests that the moist bias found in many GCMs in the mid and upper troposphere most frequently results from an excessive diffusion during vertical water vapor transport. This study demonstrates the added value of water vapor isotopic measurements for interpreting shortcomings in the simulation of RH by climate models.
UR - http://www.scopus.com/inward/record.url?scp=84863246372&partnerID=8YFLogxK
U2 - 10.1029/2011JD016623
DO - 10.1029/2011JD016623
M3 - Article
AN - SCOPUS:84863246372
SN - 0148-0227
VL - 117
JO - Journal of Geophysical Research C: Oceans
JF - Journal of Geophysical Research C: Oceans
IS - 5
M1 - D05304
ER -