Ming Cheng, Lei Zhong, Yaoming Ma, Han Ma, Yaoxin Chang, Peizhen Li, Meilin Cheng, Xian Wang, Nan Ge
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The results show that 1) ET uncertainties quantified via the MC method are lower in RS-based ET products (5.95 vs. 7.06 mm month<sup>−1</sup>) than in LSM ET products (10.22 vs. 17.97 mm month<sup>−1</sup>) and reanalysis ET estimates (7.27 vs. 12.26 mm month<sup>−1</sup>). 2) A multisource evapotranspiration (MET) dataset is generated at a monthly temporal scale with a spatial resolution of 0.25° across the TP during 2005–15. MET has better performance than any individual product. 3) Based on the fusion product, the total ET amount over the TP and its patterns of spatiotemporal variability are clearly identified. The annual total ET over the entire TP is approximately 380.60 mm. Additionally, an increasing trend of 1.59±0.85 mm yr<sup>−1</sup> over the TP is shown during 2005–15. 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引用次数: 0
摘要
蒸散(ET)是陆地水、碳和能量循环中的一个重要变量。目前,已有大量多源蒸散发产品。然而,由于观测资料稀少,在青藏高原(TP)等偏远复杂地区评估和整合蒸散发产品面临巨大挑战。本文首次评估了多重配准(MC)方法在青藏高原的适用性,并进一步分析了多源 ET 产品(基于再分析、遥感和地表模式)的不确定性,为 ET 数据融合提供了理论依据。结果表明:1)通过 MC 方法量化的蒸散发不确定性在基于 RS 的蒸散发产品中(5.95 vs. 7.06 mm month-1)低于基于 LSM 的蒸散发产品(10.22 vs. 17.97 mm month-1)和基于再分析的蒸散发估计值(7.27 vs. 12.26 mm month-1)。2) 在 2005-15 年期间,以每月时间尺度生成了一个多源蒸散(MET)数据集,其空间分辨率为 0.25°,横跨整个大陆架。MET 的性能优于任何单个产品。3) 根据融合产品,可以清楚地确定整个大陆坡的总蒸散发量及其时空变化规律。整个大洋洲的年蒸散发总量约为 380.60 毫米。此外,2005-15 年期间,整个干 旱地区的蒸散发总量呈每年 1.59±0.85 毫米的增长趋势。这项研究为今后在大埔及周边地区开展水和能量循环以及水资源管理研究奠定了基础。
A Study on the Assessment and Integration of Multi-Source Evapotranspiration Products over the Tibetan Plateau
Evapotranspiration (ET) is a crucial variable in the terrestrial water, carbon, and energy cycles. At present, a large number of multisource ET products exist. Due to sparse observations, however, great challenges exist in the evaluation and integration of ET products in remote and complex areas such as the Tibetan Plateau (TP). In this paper, the applicability of the multiple collocation (MC) method over the TP is evaluated for the first time, and the uncertainty of multisource ET products (based on reanalysis, remote sensing, and land surface models) is further analyzed, which provides a theoretical basis for ET data fusion. The results show that 1) ET uncertainties quantified via the MC method are lower in RS-based ET products (5.95 vs. 7.06 mm month−1) than in LSM ET products (10.22 vs. 17.97 mm month−1) and reanalysis ET estimates (7.27 vs. 12.26 mm month−1). 2) A multisource evapotranspiration (MET) dataset is generated at a monthly temporal scale with a spatial resolution of 0.25° across the TP during 2005–15. MET has better performance than any individual product. 3) Based on the fusion product, the total ET amount over the TP and its patterns of spatiotemporal variability are clearly identified. The annual total ET over the entire TP is approximately 380.60 mm. Additionally, an increasing trend of 1.59±0.85 mm yr−1 over the TP is shown during 2005–15. This study provides a basis for future studies on water and energy cycles and water resource management over the TP and surrounding regions.
期刊介绍:
Advances in Atmospheric Sciences, launched in 1984, aims to rapidly publish original scientific papers on the dynamics, physics and chemistry of the atmosphere and ocean. It covers the latest achievements and developments in the atmospheric sciences, including marine meteorology and meteorology-associated geophysics, as well as the theoretical and practical aspects of these disciplines.
Papers on weather systems, numerical weather prediction, climate dynamics and variability, satellite meteorology, remote sensing, air chemistry and the boundary layer, clouds and weather modification, can be found in the journal. Papers describing the application of new mathematics or new instruments are also collected here.