模型和观测结果中由大气阻塞驱动的北极暖-欧亚冷格局

Zachary Kaufman, N. Feldl, Claudie Beaulieu
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引用次数: 0

摘要

近几十年来,北极变暖和海冰消失与欧亚大陆冬季长期变冷的趋势相吻合。观察到的这种北极变暖-欧亚变冷的模式偶尔被归因于海冰迫使中纬度大气环流发生变化,这意味着是人为原因造成的。然而,全面的气候变化模拟并没有产生欧亚大陆变冷的现象,反而表明非受迫的大气变率发挥了作用。本研究试图通过开发一种统计方法来直接比较北极与中纬度的相互作用,从而澄清这种模式与观测差异的来源。在历史模拟和观测中,我们首先确定乌拉尔阻塞是海冰、温度和环流异常的主要因果驱动因素,与 "温暖北极-寒冷欧亚 "模式一致。接下来,我们量化了对乌拉尔阻塞的不同瞬态响应,这些响应解释了历史上欧亚大陆温度的模式-观测差异。观测到的 1988-2012 年欧亚大陆降温是对乌拉尔海平面气压明显正向趋势的反应,暂时掩盖了中纬度的长期变暖。观测到的这一海平面气压趋势位于完全耦合的大集合模拟变率的外缘,其中较小的海平面气压趋势对欧亚大陆的集合平均温度趋势影响甚微。考虑到这些差异,观测到的趋势和模拟的趋势非常一致。最后,我们量化了海冰消失对观测到的乌拉尔海平面气压趋势大小的影响,这种影响在历史模拟中是不存在的。这些结果表明,海冰消失和对流层变率在欧亚大陆降温过程中都能发挥作用。此外,通过对模型和观测数据进行直接比较,我们揭示了北极暖-欧亚冷模式的因果结构特征中的一个关键差异,这将为当前解释气候变化模拟中缺乏欧亚变冷的原因提供指导。
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Warm Arctic-cold Eurasia pattern driven by atmospheric blocking in models and observations
In recent decades, Arctic-amplified warming and sea-ice loss coincided with a prolonged wintertime Eurasian cooling trend. This observed Warm Arctic-Cold Eurasia pattern has occasionally been attributed to sea-ice forced changes in the midlatitude atmospheric circulation, implying an anthropogenic cause. However, comprehensive climate change simulations do not produce Eurasian cooling, instead suggesting a role for unforced atmospheric variability. This study seeks to clarify the source of this model-observation discrepancy by developing a statistical approach that enables direct comparison of Arctic-midlatitude interactions. In both historical simulations and observations, we first identify Ural blocking as the primary causal driver of sea ice, temperature, and circulation anomalies consistent with the Warm Arctic-Cold Eurasia pattern. Next, we quantify distinct transient responses to this Ural blocking, which explain the model-observation discrepancy in historical Eurasian temperature. Observed 1988-2012 Eurasian cooling occurs in response to a pronounced positive trend in Ural sea-level pressure, temporarily masking long-term midlatitude warming. This observed sea-level pressure trend lies at the outer edge of simulated variability in a fully coupled large ensemble, where smaller sea-level pressure trends have little impact on the ensemble mean temperature trend over Eurasia. Accounting for these differences bring observed and simulated trends into remarkable agreement. Finally, we quantify the influence of sea-ice loss on the magnitude of the observed Ural sea-level pressure trend, an effect that is absent in historical simulations. These results illustrate that sea-ice loss and tropospheric variability can both play a role in producing Eurasian cooling. Furthermore, by conducting a direct model-observation comparison, we reveal a key difference in the causal structures characterizing the Warm Arctic-Cold Eurasia Pattern, which will guide ongoing efforts to explain the lack of Eurasian cooling in climate change simulations.
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