Variation in the surface heat flux on the north and south slopes of Mount Qomolangma

IF 2.3 4区 地球科学 Q3 METEOROLOGY & ATMOSPHERIC SCIENCES Atmospheric and Oceanic Science Letters Pub Date : 2024-09-01 DOI:10.1016/j.aosl.2024.100513
Yonghao Jiang , Maoshan Li , Yuchen Liu , Ting Wang , Pei Xu , Yaoming Ma , Fanglin Sun
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Abstract

The distinctive conditions present on the north and south slopes of Mount Qomolangma, along with the intricate variations in the underlying surfaces, result in notable variations in the surface energy flux patterns of the two slopes. In this paper, data from TESEBS (Topographical Enhanced Surface Energy Balance System), remote sensing data from eight cloud-free scenarios, and observational data from nine stations are utilized to examine the fluctuations in the surface heat flux on both slopes. The inclusion of MCD43A3 satellite data enhances the surface albedo, contributing to more accurate simulation outcomes. The model results are validated using observational data. The RMSEs of the net radiation, ground heat, sensible heat, and latent heat flux are 40.73, 17.09, 33.26, and 30.91 W m−2, respectively. The net radiation flux is greater on the south slope and exhibits a rapid decline from summer to autumn. Due to the influence of the monsoon, on the north slope, the maximum sensible heat flux occurs in the pre-monsoon period in summer and the maximum latent heat flux occurs during the monsoon. The south slope experiences the highest latent heat flux in summer. The dominant flux on the north slope is sensible heat, while it is latent heat on the south slope. The seasonal variations in the ground heat flux are more pronounced on the south slope than on the north slope. Except in summer, the ground heat flux on the north slope surpasses that on the south slope.

摘要

珠穆朗玛峰南北坡独特的地形条件和复杂的下垫面, 导致了南北坡地表通量分布的显著差异. 本文利用地形增强地表能量平衡模式 (Topographical Enhanced Surface Energy Balance System (TESEBS)), 遥感数据和站点观测数据, 对季风和非季风期南北坡的地表热通量变化进行了研究. 首先, 把MCD43A3卫星数据加入TESEBS, 改进了地表反照率, 使模拟结果更准确. 受季风影响, 北坡季风期感热通量最大值出现在季风前期, 潜热通量最大值出现在季风期. 南坡季风期潜热通量最大. 全年北坡以感热交换为主, 南坡以潜热交换为主. 土壤热通量的季节变化在南坡比北坡更明显.

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珠穆朗玛峰南北坡地表热通量的变化
由于珠穆朗玛峰南北两坡的地形条件各不相同,加上地表的复杂变化,导致两坡的地表能量通量模式存在明显差异。本文利用 TESEBS(地形增强地表能量平衡系统)数据、8 个无云场景的遥感数据和 9 个观测站的观测数据,研究了两个山坡地表热通量的波动情况。MCD43A3 卫星数据的加入增强了地表反照率,有助于获得更精确的模拟结果。利用观测数据对模型结果进行了验证。净辐射、地热、显热和潜热通量的均方根误差分别为 40.73、17.09、33.26 和 30.91 W m-2。南坡的净辐射通量较大,从夏季到秋季呈快速下降趋势。由于季风的影响,北坡的最大显热通量出现在夏季季风前期,最大潜热通量出现在季风期间。南坡夏季的潜热通量最大。北坡的主要通量是显热,而南坡则是潜热。南坡地热通量的季节变化比北坡更明显。摘要 珠穆朗玛峰南北坡独特的地形条件和复杂的下垫面,导致了南北坡地表通量分布的显著差异。本文利用地形增强地表能量平衡模式 (Topographical Enhanced Surface Energy Balance System, TESEBS), 遥感数据和站点观测数据, 对季风和非季风期南北坡的地表热通量变化进行了研究。首先,把 mcd43a3 卫星数据加入 tesebs, 改进了地表反照率, 使模拟结果更准确。受季风影响, 北坡季风期感热通量最大值出现在季风前期, 潜热通量最大值出现在季风期.南坡季风期潜热通量最大。全年北坡以感热交换为主,南坡以潜热交换为主。土壤热通量的季节变化在南坡比北坡更明显。
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来源期刊
Atmospheric and Oceanic Science Letters
Atmospheric and Oceanic Science Letters METEOROLOGY & ATMOSPHERIC SCIENCES-
CiteScore
4.20
自引率
8.70%
发文量
925
审稿时长
12 weeks
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