基于干湿边界的非线性理论陆面蒸散估算双源梯形模型

IF 2.8 3区环境科学与生态学 Q2 WATER RESOURCES

Hydrological Sciences Journal-Journal Des Sciences Hydrologiques Pub Date : 2023-07-24 DOI:10.1080/02626667.2023.2224921

Han Chen, J. Huang, S. S. Dash, E. McBean, Vijay Singh, Hansheng Li, Yizhao Wei, Pengwei Zhang, Ziqi Zhou

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引用次数: 0

摘要

摘要众所周知，地表温度植被覆盖率梯形框架的干湿边界随植被覆盖率呈线性变化。在本研究中，对理论端元算法进行了修改，以连续估计不同植被条件下的干/湿端元，导致理论干/湿边界变得非线性。研究结果表明，非线性干/湿边界通常低于传统的线性干/湿界限。此外，与线性边界方案相比，本文采用的非线性边界方案在估计潜热通量（LE）和植被潜热通量分数（LEv/LE）方面提供了更好的性能。空气动力学和热力学粗糙度长度以及空气动力学阻力的参数方案是导致干/湿边界特性高度非线性的主要驱动因素。该研究增强了LST-fc梯形框架中的物理过程描述，提高了区域LE及其分量的预测精度。

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A non-linear theoretical dry/wet boundary-based two-source trapezoid model for estimation of land surface evapotranspiration

ABSTRACT It is well known that the dry/wet boundaries of land surface temperature fractional vegetation coverage (LSTfc) trapezoid framework vary linearly with vegetation coverage (fc). In this study, the theoretical end-members algorithm is modified to continuously estimate the dry/wet end-members under varying vegetation conditions, causing the theoretical dry/wet boundaries to become non-linear. The findings revealed that the non-linear dry/wet boundaries were generally below the conventional linear dry/wet boundaries. Furthermore, the non-linear boundary scheme adopted herein provided better performance in estimating the latent heat flux (LE) and vegetation latent heat flux fraction (LEv/LE) compared to the linear boundary scheme. The parametric schemes of aerodynamic and thermodynamic roughness length and the aerodynamic resistance were the major drivers that result in dry/wet boundaries characteristics being highly non-linear. This study enhanced the physical process description in the LST-fc trapezoid framework and improved the prediction accuracy of regional LE and its components.

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来源期刊

Hydrological Sciences Journal-Journal Des Sciences Hydrologiques 环境科学-水资源

CiteScore

6.60

自引率

11.40%

发文量

144

审稿时长

9.8 months

期刊介绍： Hydrological Sciences Journal is an international journal focused on hydrology and the relationship of water to atmospheric processes and climate. Hydrological Sciences Journal is the official journal of the International Association of Hydrological Sciences (IAHS). Hydrological Sciences Journal aims to provide a forum for original papers and for the exchange of information and views on significant developments in hydrology worldwide on subjects including: Hydrological cycle and processes Surface water Groundwater Water resource systems and management Geographical factors Earth and atmospheric processes Hydrological extremes and their impact Hydrological Sciences Journal offers a variety of formats for paper submission, including original articles, scientific notes, discussions, and rapid communications.