陆地表面积雪过程对北极稳定边界层的影响

Xiaodong Hong, Qingfang Jiang
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摘要

利用海军的海洋/大气中尺度耦合预报系统(COAMPS)研究了陆地表面雪过程对北极稳定边界层(ASBL)的影响,以减少陆地表面和大气之间解耦引起的冷偏差。利用 COAMPS 预测强迫,对改进了积雪过程的 Noah 陆面模式(LSM)进行了为期一个月的检验。新的积雪物理学表明,积雪特性、粗糙度长度和显热通量都按照预期进行了修改,以弥补旧 LSM 的不足。这些新的积雪过程被纳入 COAMPS Noah LSM,并使用新旧 Noah LSM 对 2021 年 1 月进行了 48 小时预报,每 6 小时数据同化更新一次。48 小时预报的标准验证使用了所有可用的 ADP 观测数据集和来自陆地信息系统 (LIS) 分析的积雪深度。统计结果表明,新的积雪物理方法减少了月平均低温偏差∼1 °C。新的积雪物理场的地表反演强度较弱,湍流动能(TKE)较强,因此涡流混合明显增强,从而提供了更高的边界层。模拟结果还表明,从全球预报或分析中获得的不同横向边界条件对新雪景物理学结果的影响微乎其微。这项研究强调了诺亚低层大气研究中修订的雪物理学对于减少解耦问题、改进预报和研究北极地区上空的 ASBL 物理的重要性。
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Impact of land surface snow processes on the Arctic stable boundary layer
The impact of land surface snow processes on the Arctic stable boundary layer (ASBL) is investigated using the Navy’s Coupled Ocean/Atmosphere Mesoscale Prediction System (COAMPS) to reduce the cold bias caused by decoupling between the land surface and atmosphere. The Noah land surface model (LSM) with improved snow processes is examined using COAMPS forecast forcing in the one-dimension mode for one month. The new snow physics shows that the snow properties, roughness length, and sensible heat flux are modified as expected to compensate for the old LSM deficiency. These new snow processes are incorporated into the COAMPS Noah LSM, and the 48-h forecasts using both old and new Noah LSMs are performed for January 2021 with every 6-h data assimilation update cycle. Standard verifications of the 48-h forecasts have used all available ADP observational data sets and the snow depth from the Land Information System (LIS) analyses. The statistics have shown reduced monthly mean cold biases ∼1 °C by the new snow physics. The weaker strength of surface inversion and stronger turbulence kinetic energy (TKE) from the new snow physics provides a higher boundary layer due to significantly stronger eddy mixing. The simulations have also shown the insignificant impact of different lateral boundary conditions obtained from the global forecasts or analyses on the results of the new snow physics. This study highlights the importance of the revised snow physics in Noah LSM for reducing the decoupling problem, improving the forecasts, and studying ASBL physics over the Arctic region.
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