Abstract

A comprehensive understanding of temporal variability of subsurface soil moisture (SM) is paramount in hydrological and agricultural applications such as rainfed farming and irrigation. Since the SMOS (Soil Moisture and Ocean Salinity) mission was launched in 2009, globally available satellite SM retrievals have been used to investigate SM dynamics, based on the fact that useful information about subsurface SM is contained in their time series. SM along the depth profile is influenced by atmospheric forcing and local SM properties. Until now, subsurface SM was estimated by weighting preceding information of remotely sensed surface SM time series according to an optimized depth-specific characteristic time length. However, especially in regions with extreme SM conditions, the response time is supposed to be seasonally variable and depends on related processes occurring at different timescales. Aim of this study was to quantify the response time by means of the time lag between the trend series of satellite and in-situ SM observations using a Dynamic Time Warping (DTW) technique. DTW was applied to the SMOS satellite SM L4 product at 1 km resolution developed by the Barcelona Expert Center (BEC), and in-situ near-surface and root-zone SM of four representative stations at multiple depths, located in the Soil Moisture Measurements Station Network of the University of Salamanca (REMEDHUS) in Western Spain. DTW was customized to control the rate of accumulation and reduction of time lag during wetting and drying conditions and to consider the onset dates of pronounced precipitation events to increase sensitivity to prominent features of the input series. The temporal variability of climate factors in combination with crop growing seasons were used to indicate prevailing SM-related processes. Hereby, a comparison of long-term precipitation recordings and estimations of potential evapotranspiration (PET) allowed us to estimate SM seasons. The spatial heterogeneity of land use was analyzed by means of high-resolution images of Normalized Difference Vegetation Index (NDVI) from Sentinel-2 to provide information about the level of spatial representativeness of SMOS observations to each in-situ station. Results of the spatio-temporal analysis of the study were then evaluated to understand seasonally and spatially changing patterns in time lag. The time lag evolution describes a variable characteristic time length by considering the relevant processes which link SMOS and in-situ SM observation, which is an important step to accurately infer subsurface SM from satellite time series. At a further stage, the approach needs to be applied to different SM networks to understand the seasonal, climate- and site-specific characteristic behaviour of time lag and to decide, whether general conclusions can be drawn.

Highlights

  • Soil moisture (SM) is recognized as an essential climate variable (ECV) and it plays an important role in agricultural applications including drought monitoring and rainfall estimations, weather forecasting and climate models across different spatial and temporal scales

  • Dynamic Time Warping (DTW) was applied to Soil Moisture and Ocean Salinity (SMOS) and in-situ soil moisture (SM) observations and the single steps are explained for station E10 in 2017

  • This study presented a methodology to estimate the response time between SMOS satellite and point-scale in-situ SM observations at near surface and root zone

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Summary

Introduction

Soil moisture (SM) is recognized as an essential climate variable (ECV) and it plays an important role in agricultural applications including drought monitoring and rainfall estimations, weather forecasting and climate models across different spatial and temporal scales. Surface water balance comprises processes such as infiltration, runoff, evaporation and transpiration, and subsurface water movements including recharge and drainage. These processes occur at different temporal scales and knowledge about their variability is critical to effectively determine crop growing seasons and to schedule irrigation if necessary [3]. Long-lasting events such as heat waves and precipitation hold off become more frequent [4]. An understanding of both near-surface and root-zone SM is of key importance to study water scarcity and drought phenomena [5,6]

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