The influence of bias correction of global climate models prior to dynamical downscaling on projections of changes in climate: a case study over the CORDEX-Australasia domain
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引用次数: 0
Abstract
Abstract We investigate the influence of bias correction of Global Climate Models (GCMs) prior to dynamical downscaling using regional climate models (RCMs), on the change in climate projected. We use 4 GCMs which are bias corrected against ERA-Interim re-analysis as a surrogate truth, and carry out bias corrected and non-bias corrected simulations over the CORDEX Australasia domain using the Weather Research and Forecasting model. Our results show that when considering the effect of bias correction on current and future climate separately, bias correction has a large influence on precipitation and temperature, especially for models which are known to have large biases. However, when considering the change in climate, i.e the $$\Delta$$ Δ change (future minus current), we found that while differences between bias-corrected and non-corrected RCM simulations can be substantial (e.g. more than $$1\,^\circ$$ 1∘ C for temperatures) these differences are generally smaller than the models’ inter-annual variability. Overall, averaged across all variables, bias corrected boundary conditions produce an overall reduction in the range, standard deviation and mean absolute deviation of the change in climate projected by the 4 models tested, over 61.5%, 62% and 58% of land area, with a larger reduction for precipitation as compared to temperature indices. In addition, we show that changes in the $$\Delta$$ Δ change for DJF tasmax are broadly linked to precipitation changes and consequently soil moisture and surface sensible heat flux and changes in the $$\Delta$$ Δ changefor JJA tasmin are linked to downward longwave heat flux. This study shows that bias correction of GCMs against re-analysis prior to dynamical downscaling can increase our confidence in projected future changes produced by downscaled ensembles.
摘要研究了区域气候模式(RCMs)动态降尺度前全球气候模式(GCMs)的偏差校正对预估气候变化的影响。我们使用4个针对ERA-Interim再分析进行偏差校正的gcm作为替代真值,并使用天气研究与预报模型在CORDEX Australasia区域进行了偏差校正和非偏差校正的模拟。结果表明,当分别考虑偏差校正对当前和未来气候的影响时,偏差校正对降水和温度的影响较大,特别是对于已知存在较大偏差的模式。然而,当考虑到气候变化,即$$\Delta$$ Δ变化(未来减去当前)时,我们发现,虽然偏差校正和未校正的RCM模拟之间的差异可能很大(例如,温度大于$$1\,^\circ$$°C),但这些差异通常小于模式的年际变率。总的来说,在所有变量的平均值上,经过偏差校正的边界条件使经测试的4种模式预估的气候变化的范围、标准差和平均绝对偏差总体上减小,超过61.5%, 62% and 58% of land area, with a larger reduction for precipitation as compared to temperature indices. In addition, we show that changes in the $$\Delta$$ Δ change for DJF tasmax are broadly linked to precipitation changes and consequently soil moisture and surface sensible heat flux and changes in the $$\Delta$$ Δ changefor JJA tasmin are linked to downward longwave heat flux. This study shows that bias correction of GCMs against re-analysis prior to dynamical downscaling can increase our confidence in projected future changes produced by downscaled ensembles.
期刊介绍:
The international journal Climate Dynamics provides for the publication of high-quality research on all aspects of the dynamics of the global climate system.
Coverage includes original paleoclimatic, diagnostic, analytical and numerical modeling research on the structure and behavior of the atmosphere, oceans, cryosphere, biomass and land surface as interacting components of the dynamics of global climate. Contributions are focused on selected aspects of climate dynamics on particular scales of space or time.
The journal also publishes reviews and papers emphasizing an integrated view of the physical and biogeochemical processes governing climate and climate change.