Multi-Model Projection of July-August Climate Extreme Changes over China under CO2 Doubling. Part II: Temperature

This is the second part of the authors' analysis on the output of 24 coupled climate models from the Twentieth-Century Climate in Coupled Models (20C3M) experiment and 1% per year CO2 increase experiment (to doubling) (1pctto2x) of phase 3 of the Coupled Model Inter-comparison Project (CMIP3). The study focuses on the potential changes of July-August temperature extremes over China. The pattern correlation coefficients of the simulated temperature with the observations are 0.6-0.9, which are higher than the results for precipitation. However, most models have cold bias compared to observation, with a larger cold bias over western China (>5 degrees C) than over eastern China (<2 degrees C). The multi-model ensemble (MME) exhibits a significant increase of temperature under the 1pctto2x scenario. The amplitude of the MME warming shows a northwest southeast decreasing gradient. The warming spread among the models (similar to 1 degrees C-2 degrees C) is less than MME warming (similar to 2 degrees C-4 degrees C), indicating a relatively robust temperature change under CO2 doubling. Further analysis of Geophysical Fluid Dynamics Laboratory coupled climate model version 2.1 (GFDL-CM2.1) simulations suggests that the warming pattern may be related to heat transport by summer monsoons. The contrast of cloud effects also has contributions. The different vertical structures of warming over northwestern China and southeastern China may be attributed to the different natures of vertical circulations. The deep, moist convection over southeastern China is an effective mechanism for transporting the warming upward, leading to more upper-level warming. In northwestern China, the warming is more surface-orientated, possibly clue to the shallow, dry convection.