Impact of the selected boundary layer schemes and enhanced horizontal resolution on the Weather Research and Forecasting model performance on James Ross Island, Antarctic Peninsula

IF 0.5 Q4 ECOLOGY

Czech Polar Reports Pub Date : 2022-09-05 DOI:10.5817/cpr2022-1-2

M. Matějka, K. Láska

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Abstract

The output of the various Weather Research and Forecasting (WRF) model configurations was compared with ground-based observations in the northern part of James Ross Island, Antarctic Peninsula. In this region, a network of automatic weather stations deployed at ice-free sites (as well as small glaciers) is operated by the Czech Antarctic Research Programme. Data from these stations provide a unique opportunity to evaluate the WRF model in a complex terrain of James Ross Island. The model was forced by the ERA5 reanalysis data and the University of Bremen sea ice data. The model configurations include a novel Three-Dimensional Scale-Adaptive Turbulent Kinetic Energy (3D TKE) planetary boundary layer scheme and a more traditional Quasi-Normal Scale Elimination (QNSE) scheme. Impact of model horizontal resolution was evaluated by running simulations in both 700 m and 300 m. The validation period, 25 May 2019 to 12 June 2019, was selected to cover different stratification regimes of air temperature and a significant snowfall event. Air temperature was simulated well except for strong low-level inversions. These inversions occurred in 44% of all cases and contributed to a higher mean bias (2.0–2.9°C) at low-elevation sites than at high altitude sites (0.2–0.6°C). The selection of the 3D TKE scheme led to improvement at low-elevation sites; at high altitude sites, the differences between model configurations were rather small. The best performance in wind speed simulation was achieved with the combination of the 3D TKE scheme and 300 m model resolution. The most important improvement was decrease of bias at a coastal Mendel Station from 3.5 m·s‑1 with the QNSE scheme on the 700 m grid to 1.2 m·s‑1 with the 3D TKE scheme on the 300 m grid. The WRF model was also proven to simulate a large snowfall event with a good correspondence with the observed snow height.

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选定边界层方案和提高水平分辨率对南极半岛James Ross岛天气研究与预报模式性能的影响

将各种气象研究与预报(WRF)模式配置的输出与南极半岛詹姆斯罗斯岛北部的地面观测结果进行了比较。在这个地区，捷克南极研究方案在无冰地点(以及小冰川)部署了一个自动气象站网络。来自这些台站的数据为在詹姆斯罗斯岛复杂地形中评估WRF模型提供了独特的机会。该模型是由ERA5再分析数据和不来梅大学海冰数据强制建立的。模型配置包括一种新的三维尺度自适应湍流动能(3D TKE)行星边界层格式和一种更传统的准正尺度消除(QNSE)格式。通过在700米和300米进行模拟，评估了模型水平分辨率的影响。验证期为2019年5月25日至2019年6月12日，选择了不同的气温分层制度和一次重大降雪事件。除强烈的低空逆温外，气温模拟良好。所有病例中有44%发生逆温，低海拔地区的平均偏倚(2.0-2.9°C)高于高海拔地区(0.2-0.6°C)。3D TKE方案的选择改善了低海拔地区的地形;在高海拔地区，模型配置之间的差异相当小。三维TKE方案与300 m模型分辨率相结合的风速模拟效果最好。最重要的改进是沿海Mendel站的偏差从700 m网格上使用QNSE方案的3.5 m·s‑1降低到300 m网格上使用3D TKE方案的1.2 m·s‑1。WRF模式也被证明可以模拟一个大的降雪事件，与观测到的雪高有很好的对应关系。

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来源期刊

Czech Polar Reports Agricultural and Biological Sciences-Agricultural and Biological Sciences (all)

CiteScore

1.30

自引率

10.00%

发文量

期刊介绍： Czech Polar Reports is an international, multidisciplinary, peer-reviewed journal. It is issued 2 times a year. The journal is dedicated to provide original research papers for sciences related to the polar regions and other planets with polar analogues. Czech Polar Reports covers the disciplines listed below. polar paleontology, geology, geochemistry, geomorphology, glaciology, climatology, hydrology, pedology, biochemistry, ecology, environmental science, microbiology, plant and animal biology including marine biology.