Initialization shock in the ocean circulation reduces skill in decadal predictions of the North Atlantic subpolar gyre

IF 3.3 Q2 ENVIRONMENTAL SCIENCES
Iuliia Polkova, D. Swingedouw, L. Hermanson, A. Köhl, D. Stammer, Doug M. Smith, J. Kröger, I. Bethke, Xiaosong Yang, Liping Zhang, D. Nicolì, P. Athanasiadis, M. Karami, K. Pankatz, H. Pohlmann, Bo Wu, R. Bilbao, Pablo Ortega, Shuting Yang, R. Sospedra‐Alfonso, W. Merryfield, T. Kataoka, H. Tatebe, Yukiko Imada, M. Ishii, R. Matear
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Abstract

Due to large northward heat transport, the Atlantic meridional overturning circulation (AMOC) strongly affects the climate of various regions. Its internal variability has been shown to be predictable decades ahead within climate models, providing the hope that synchronizing ocean circulation with observations can improve decadal predictions, notably of the North Atlantic subpolar gyre (SPG). Climate predictions require a starting point which is a reconstruction of the past climate. This is usually performed with data assimilation methods that blend available observations and climate model states together. There is no unique method to derive the initial conditions. Moreover, this can be performed using full-field observations or their anomalies superimposed on the model's climatology to avoid strong drifts in predictions. How critical ocean circulation drifts are for prediction skill has not been assessed yet. We analyze this possible connection using the dataset of 12 decadal prediction systems from the World Meteorological Organization Lead Centre for Annual-to-Decadal Climate Prediction. We find a variety of initial AMOC errors within the predictions related to a dynamically imbalanced ocean states leading to strongly displaced or multiple maxima in the overturning structures. This likely results in a blend of what is known as model drift and initial shock. We identify that the AMOC initialization influences the quality of the SPG predictions. When predictions show a large initial error in their AMOC, they usually have low skill for predicting internal variability of the SPG for a time horizon of 6-10 years. Full-field initialized predictions with low AMOC drift show better SPG skill than those with a large AMOC drift. Nevertheless, while the anomaly-initialized predictions do not experience large drifts, they show low SPG skill when skill also present in historical runs is removed using a residual correlation metric. Thus, reducing initial shock and model biases for the ocean circulation in prediction systems might help to improve their prediction for the SPG beyond 5 years. Climate predictions could also benefit from quality-check procedure for assimilation/initialization because currently the research groups only reveal the problems in initialization once the set of predictions has been completed, which is an expensive effort.
海洋环流的初始化冲击降低了北大西洋副极地涡旋十年期预测的准确性
大西洋经向翻转环流(AMOC)由于大量的向北热输送,对各地区的气候有强烈的影响。它的内部变化已被证明可以在气候模式中预测未来几十年,这提供了将海洋环流与观测数据同步可以改进十年预测的希望,特别是北大西洋亚极地环流(SPG)。气候预测需要一个起点,即对过去气候的重建。这通常是通过混合现有观测和气候模式状态的数据同化方法来完成的。没有唯一的方法来推导初始条件。此外,这可以使用全场观测或将其异常与模式的气候学叠加来实现,以避免预测中的强烈漂移。海洋环流漂移对预测技术有多重要还没有得到评估。我们利用世界气象组织年至年代际气候预测领导中心的12个年代际预测系统的数据集分析了这种可能的联系。我们在预测中发现了各种初始AMOC误差,这些误差与动态不平衡的海洋状态有关,这些海洋状态导致强烈位移或在倾覆结构中出现多个极大值。这可能会导致所谓的模型漂移和初始冲击的混合。我们发现AMOC初始化会影响SPG预测的质量。当预测在AMOC中显示出较大的初始误差时,他们通常在预测6-10年时间范围内SPG的内部变异性方面具有较低的技能。AMOC漂移小的全场初始化预测比AMOC漂移大的全场初始化预测显示出更好的SPG技能。然而,尽管异常初始化的预测没有经历大的漂移,但当使用残差相关度量去除历史运行中也存在的技能时,它们显示出较低的火炮技能。因此,减少预测系统中海洋环流的初始冲击和模式偏差可能有助于提高对5年以后SPG的预测。气候预测也可以从同化/初始化的质量检查程序中受益,因为目前的研究小组只在预测集完成后才揭示初始化中的问题,这是一项昂贵的工作。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Frontiers in Climate
Frontiers in Climate Environmental Science-Environmental Science (miscellaneous)
CiteScore
4.50
自引率
0.00%
发文量
233
审稿时长
15 weeks
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