Combined measurements of 17Oexcess and d-excess in African monsoon precipitation: Implications for evaluating convective parameterizations

Water stable isotopes ( delta 18O, ID) are useful tools to depict and to understand the atmospheric water cycle. In tropical regions, they record the variations of convective activity and their implementation in convection schemes brings constraints on our understanding and parameterization of this...

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Bibliographic Details
Published in:Earth and planetary science letters 2010-09, Vol.298 (1-2), p.104-112
Main Authors: Landais, A, Risi, C, Bony, S, Vimeux, F, Descroix, L, Falourd, S, Bouygues, A
Format: Article
Language:English
Subjects:
Atmospherics
Isotopes
Monsoons
Parametrization
Relative humidity
Representations
Squalls
Tropical regions
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Summary:Water stable isotopes ( delta 18O, ID) are useful tools to depict and to understand the atmospheric water cycle. In tropical regions, they record the variations of convective activity and their implementation in convection schemes brings constraints on our understanding and parameterization of this phenomena. Here, we present for the first time measurements of a new isotopic marker of the hydrological cycle (17Oexcess resulting from the combination of delta 17O and delta 18O of water) in convective regions on two different time scales: (i) during the African monsoon onset and intra-seasonal variability (Banizoumbou, 2006) and (ii) during the squall line of the 11th of August 2006 (Niamey). 17Oexcess responds to the monsoon onset by a 30 per meg increase as well as to different convective processes in squall lines by 20 per meg variations. These variations parallel those of d-excess at first order and display significant correlation with relative humidity in the lower troposphere. Still, higher correlation coefficients are observed between d-excess and relative humidity than between 17Oexcess and relative humidity, suggesting a higher influence of relative humidity on d-excess than on 17Oexcess. Using a simple reevaporation model and a more sophisticated 2D model of a squall line, we show that reevaporation is the process explaining the increase of d-excess and 17Oexcess with relative humidity for these two studies. We also show that the combination of 17Oexcess and d-excess is a powerful tool to constrain the representation of isotopic processes during rain reevaporation. In turn, a good representation of such processes enables to use water isotopes to evaluate convective parameterization in atmospheric models.
ISSN:0012-821X
DOI:10.1016/j.epsl.2010.07.033