Evapotranspiration and evaporation/transpiration partitioning with dual source energy balance models in agricultural lands

Q3 Earth and Planetary Sciences

Proceedings of the International Association of Hydrological Sciences Pub Date : 2018-12-18 DOI:10.5194/PIAHS-380-17-2018

G. Boulet, E. Delogu, S. Saadi, W. Chebbi, A. Olioso, B. Mougenot, P. Fanise, Z. Lili-Chabaane, J. Lagouarde

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引用次数: 9

Abstract

Abstract. EvapoTranspiration (ET) is an important component of the water cycle, especially in semi-arid lands. Its quantification is crucial for a sustainable management of scarce water resources. A way to quantify ET is to exploit the available surface temperature data from remote sensing as a signature of the surface energy balance, including the latent heat flux. Remotely sensed energy balance models enable to estimate stress levels and, in turn, the water status of most continental surfaces. The evaporation and transpiration components of ET are also just as important in agricultural water management and ecosystem health monitoring. Single temperatures can be used with dual source energy balance models but rely on specific assumptions on raw levels of plant water stress to get both components out of a single source of information. Additional information from remote sensing data are thus required, either something specifically related to evaporation (such as surface water content) or transpiration (such as PRI or fluorescence). This works evaluates the SPARSE dual source energy balance model ability to compute not only total ET, but also water stress and transpiration/evaporation components. First, the theoretical limits of the ET component retrieval are assessed through a simulation experiment using both retrieval and prescribed modes of SPARSE with the sole surface temperature. A similar work is performed with an additional constraint, the topsoil surface soil moisture level, showing the significant improvement on the retrieval. Then, a flux dataset acquired over rainfed wheat is used to check the robustness of both stress levels and ET retrievals. In particular, retrieval of the evaporation and transpiration components is assessed in both conditions (forcing by the sole temperature or the combination of temperature and soil moisture). In our example, there is no significant difference in the performance of the total ET retrieval, since the evaporation rate retrieved from the sole surface temperature is already fairly close to the one we can reconstruct from observed surface soil moisture time series, but current work is underway to test it over other plots.

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基于双源能量平衡模型的农田蒸散发和蒸发/蒸腾分配

摘要蒸散发(ET)是水循环的重要组成部分，特别是在半干旱地区。它的量化对于稀缺水资源的可持续管理至关重要。量化ET的一种方法是利用遥感获得的地表温度数据作为地表能量平衡的标志，包括潜热通量。遥感能量平衡模型能够估算压力水平，进而估算大多数大陆表面的水状况。蒸散发的蒸发和蒸腾成分在农业用水管理和生态系统健康监测中也同样重要。单一温度可以用于双源能量平衡模型，但依赖于对植物水分胁迫原始水平的特定假设，以从单一信息来源中获得两个组成部分。因此需要来自遥感数据的额外信息，或者是与蒸发(如表面含水量)或蒸腾(如PRI或荧光)具体相关的信息。本文评估了稀疏双源能量平衡模型不仅计算总蒸散发，而且计算水分胁迫和蒸腾/蒸发分量的能力。首先，通过基于鞋底表面温度的稀疏检索和规定模式的模拟实验，评估了ETcomponent检索的理论极限。在进行类似的工作时，增加了一个额外的约束条件，即表层土壤水分水平，显示了检索的显着改善。然后，利用在旱作小麦上获得的通量数据集来检验胁迫水平和ET检索的适应性。特别是，在这两种条件下(由单一温度或温度和土壤湿度的组合强迫)，评估了蒸发和蒸腾分量的检索。在我们的例子中，总蒸散发检索的性能没有显著差异，因为从单一表面温度检索的蒸发速率已经相当接近我们可以从观测到的地表土壤湿度时间序列中重建的蒸发速率，但目前正在进行在其他地块上进行测试的工作。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Proceedings of the International Association of Hydrological Sciences Earth and Planetary Sciences-Earth and Planetary Sciences (all)

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12 weeks