Interannual variability of H218O in precipitation over the Asian monsoon region

Abstract

The stable isotopic composition of water has been used as a paleoproxy to reconstruct past climates over the Asian monsoon region, but the main controls on the variability of isotopes of water in precipitation have not been characterized quantitatively in this region. Therefore, we used an atmospheric general circulation model incorporating stable water isotope physics to quantitatively estimate the relative contributions to isotope variability in precipitation falling in the Asian monsoon region. As in previous research, we identified two primary factors controlling the interannual variability of δ18Oprecip (defined as (Rsample/RVSMOW - 1)×1000, where RVSMOW is the 18O ratio in Vienna Standard Mean Ocean Water) and its correlation with El Nio-Southern Oscillation (ENSO) events: the amount of precipitation at the observation site, and distillation during transport from source regions. Two sensitivity experiments revealed that distillation during transport from source regions was the dominant controlling factor; at Bangkok, Bombay, and Hong Kong, the amount of local precipitation contributed 27%, 33%, and 25% while distillation processes contributed 70%, 60%, and 70%, respectively. Similarly, distillation processes accounted for 80%, 82%, and 83% of observed differences in δ 18Oprecip between El Nio and La Nia years at these three cities, respectively. Therefore, interannual variability of δ 18Oprecip at the three stations primarily reflects distillation during transport from source regions, and it is also governed by the large-scale tropical variability (ENSO). © 2012. American Geophysical Union. All Rights Reserved.