CWRF downscaling with improved land surface initialization enhances spring-summer seasonal climate prediction skill in China

IF 4.8 2区 地球科学 Q1 METEOROLOGY & ATMOSPHERIC SCIENCES
Han Zhang, Xin-Zhong Liang, Yongjiu Dai, Lianchun Song, Qingquan Li, Fang Wang, Shulei Zhang
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Abstract

Abstract This study investigates skill enhancement in operational seasonal forecasts of Beijing Climate Center’s Climate System Model through regional Climate-Weather Research and Forecasting (CWRF) downscaling and improved land initialization in China. The downscaling mitigates regional climate biases, enhancing precipitation pattern correlations by 0.29 in spring and 0.21 in summer. It also strengthens predictive capabilities for interannual anomalies, expanding skillful temperature forecast areas by 6% in spring and 12% in summer. Remarkably, during seven of ten years with relative high predictability, the downscaling increases average seasonal precipitation anomaly correlations by 0.22 and 0.25. Additionally, substitution of initial land conditions via a Common Land Model integration reduces snow cover and cold biases across the Tibetan Plateau and Mongolia-Northeast China, consistently contributing to CWRF’s overall enhanced forecasting capabilities. Improved downscaling predictive skill is attributed to CWRF’s enhanced physics representation, accurately capturing intricate regional interactions and associated teleconnections across China, especially linked to the Tibetan Plateau’s blocking and thermal effects. In summer, CWRF predicts an intensified South Asian High alongside a strengthened East Asian Jet compared to CSM, amplifying cold air advection and warm moisture transport over central to northeast regions. Consequently, rainfall distributions and interannual anomalies over these areas experience substantial improvements. Similar enhanced circulation processes elucidate skill improvement from land initialization, where accurate specification of initial snow cover and soil temperature within sensitive regions persists in influencing local and remote circulations extending beyond two seasons. Our findings emphasize the potential of improving physics representation and surface initialization to markedly enhance regional climate predictions.
改进地表初始化的 CWRF 降尺度技术提高了中国春夏季节气候预测能力
摘要 本研究探讨了北京气候中心气候系统模式通过区域气候-天气研究和预报(CWRF)降尺度和改进陆地初始化提高业务季节预报技能的问题。降尺度措施减轻了区域气候偏差,使春季降水模式相关性提高了 0.29,夏季提高了 0.21。它还加强了对年际异常的预测能力,将春季和夏季的熟练温度预报区域分别扩大了 6% 和 12%。值得注意的是,在 10 个可预测性相对较高的年份中,有 7 个年份的降水量缩减使平均季节降水异常相关性分别提高了 0.22 和 0.25。此外,通过共用陆地模式集成替换初始陆地条件,减少了青藏高原和蒙古-中国东北地区的积雪和寒冷偏差,从而不断提高 CWRF 的整体预报能力。CWRF 强化的物理表现形式提高了降尺度预报能力,准确捕捉了中国各地错综复杂的区域相互作用和相关的远程联系,尤其是与青藏高原的阻挡和热效应有关的相互作用和联系。与 CSM 相比,在夏季,CWRF 预测南亚高气压增强,东亚喷流增强,从而放大了中部至东北部地区的冷空气对流和暖湿气流输送。因此,这些地区的降雨分布和年际异常得到了极大改善。类似的增强环流过程阐明了陆地初始化技术的改进,敏感区域内初始积雪覆盖和土壤温度的精确指定持续影响着本地和远端环流,影响范围超过两个季节。我们的研究结果强调了改进物理表示和地表初始化以显著提高区域气候预测的潜力。
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来源期刊
Journal of Climate
Journal of Climate 地学-气象与大气科学
CiteScore
9.30
自引率
14.30%
发文量
490
审稿时长
7.5 months
期刊介绍: The Journal of Climate (JCLI) (ISSN: 0894-8755; eISSN: 1520-0442) publishes research that advances basic understanding of the dynamics and physics of the climate system on large spatial scales, including variability of the atmosphere, oceans, land surface, and cryosphere; past, present, and projected future changes in the climate system; and climate simulation and prediction.
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