Vegetation signal crosstalk present in official SMAP surface soil moisture retrievals

IF 11.1 1区地球科学 Q1 ENVIRONMENTAL SCIENCES

Remote Sensing of Environment Pub Date : 2024-11-13 DOI:10.1016/j.rse.2024.114466

Wade T. Crow, Andrew F. Feldman

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引用次数: 0

Abstract

Successful surface soil moisture (SM) retrieval from space has been enabled by microwave satellite measurements of Earth's upwelling brightness temperature (T_B). Nevertheless, correction for the impact of vegetation on T_B emission remains a challenge for SM retrieval algorithms. Such correction is often performed in a simplified manner. For example, the Single Channel Algorithm (SCA) uses ancillary climatological normalized vegetation difference index values as a proxy for vegetation optical depth (τ) - resulting in SM retrievals that do not account for interannual τ variability. Official NASA Soil Moisture Active/Passive (SMAP) mission SM products are all based, to varying degrees, on the SCA. Here, we utilize an instrumental variable analysis and alternative SMAP SM retrievals derived from the Multi-Temporal Dual Channel Algorithm (MTDCA) – that better account for time variations in τ – as a benchmark for examining SMAP Level 3 SM retrievals for the presence of signal crosstalk associated with the neglect of interannual τ variability. Results suggest that failing to account for such variability introduces a spurious vegetation-based signal into monthly climatological SMAP SM anomalies. The SMAP Dual Channel Algorithm (DCA), which serves as the current SMAP baseline algorithm, reduces - but does not eliminate – this crosstalk. Results therefore suggest the need for caution when applying SMAP SM retrievals to science applications aimed at understanding SM coupling with the terrestrial biosphere.

Plain language summary

Satellite observations of natural microwave emission from Earth's land surface can be converted into estimates of both surface soil moisture and vegetation water content. Such estimates have a variety of applications. However, the separation of the vegetation signal from the soil moisture signal is challenging and often performed using only approximate methods. This paper uses a novel approach to evaluate how accurately state-of-the-art soil moisture retrieval algorithms perform such partitioning. Results suggests that spurious vegetation signals remain in existing soil moisture products - with some approaches removing it more than others. Such “crosstalk” between soil- and vegetation-based signals limits the value of existing satellite soil moisture products for agricultural and ecohydrological applications and motivates the development of improved retrieval algorithms.

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官方 SMAP 地表土壤水分检索中存在的植被信号串扰

通过微波卫星对地球上涌亮度温度（TB）的测量，可以成功地从空间进行地表土壤湿度（SM）检索。然而，修正植被对 TB 辐射的影响仍然是 SM 检索算法面临的一项挑战。这种校正通常以简化的方式进行。例如，单通道算法（SCA）使用辅助气候学归一化植被差异指数值作为植被光学深度（τ）的替代值--导致土壤水分检索不考虑年际τ变化。美国国家航空航天局（NASA）土壤水分主动/被动（SMAP）任务的官方土壤水分产品都在不同程度上基于SCA。在这里，我们利用工具变量分析和从多时空双通道算法（MTDCA）中得出的替代 SMAP SM 检索结果（更好地考虑了 τ 的时间变化）作为基准，检查 SMAP 第 3 级 SM 检索结果是否存在与忽略年际 τ 变化相关的信号串扰。结果表明，如果不考虑这种变率，就会在 SMAP SM 月度气候异常中引入虚假的植被信号。作为当前 SMAP 基线算法的 SMAP 双通道算法（DCA）可以减少--但不能消除--这种串扰。因此，结果表明，在将 SMAP SM 检索应用于旨在了解 SM 与陆地生物圈耦合的科学应用时需要谨慎。这些估算值有多种用途。然而，将植被信号从土壤水分信号中分离出来是一项挑战，通常只能使用近似方法。本文采用一种新方法来评估最先进的土壤水分检索算法如何准确地进行这种分离。结果表明，在现有的土壤水分产品中仍然存在虚假的植被信号--有些方法比其他方法更能去除这些信号。土壤和植被信号之间的这种 "串扰 "限制了现有卫星土壤水分产品在农业和生态水文应用方面的价值，并促使人们开发改进的检索算法。

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

Remote Sensing of Environment 环境科学-成像科学与照相技术

CiteScore

25.10

自引率

8.90%

发文量

455

审稿时长

53 days

期刊介绍： Remote Sensing of Environment (RSE) serves the Earth observation community by disseminating results on the theory, science, applications, and technology that contribute to advancing the field of remote sensing. With a thoroughly interdisciplinary approach, RSE encompasses terrestrial, oceanic, and atmospheric sensing. The journal emphasizes biophysical and quantitative approaches to remote sensing at local to global scales, covering a diverse range of applications and techniques. RSE serves as a vital platform for the exchange of knowledge and advancements in the dynamic field of remote sensing.