Abstract
Modeling and prediction of soil hydrologic processes require identifying soil moisture spatial-temporal patterns and effective methods allowing the data observations to be used across different spatial and temporal scales. This work presents a methodology for combining spatially- and temporally-extensive soil moisture datasets obtained in the Shale Hills Critical Zone Observatory (CZO) from 2004 to 2010. The soil moisture was investigated based on Empirical Orthogonal Function (EOF) analysis. The dominant soil moisture patterns were derived and further correlated with the soil-terrain attributes in the study area. The EOF analyses indicated that one or two EOFs of soil moisture could explain 76–89% of data variation. The primary EOF pattern had high values clustered in the valley region and, conversely, low values located in the sloping hills, with a depth-dependent correlation to which curvature, depth to bedrock, and topographic wetness index at the intermediate depths (0.4 m) exhibited the highest contributions. We suggest a novel approach to integrating the spatially-extensive manually measured datasets with the temporally-extensive automatically monitored datasets. Given the data accessibility, the current data merging framework has provided the methodology for the coupling of the mapped and monitored soil moisture datasets, as well as the conceptual coupling of slow and fast pedologic and hydrologic functions. This successful coupling implies that a combination of diverse and extensive moisture data has provided a solution of data use efficiency and, thus, exciting insights into the understanding of hydrological processes at multiple scales.
Highlights
Soil moisture is a crucial variable within earth system dynamics from regional to pedon scales [1,2].Identification and prediction of soil moisture patterns are essential in a wide range of agronomic, hydrological, pedological, and environmental studies [3,4]
We explored the Empirical Orthogonal Function (EOF) method to breakdown a more dynamic time series of soil moisture into a lesser number of orthogonal spatial EOF patterns and corresponding expansion coefficients coefficients (ECs) components
We developed a data combination approach based on EOF analysis of space-time soil moisture data at a reference Shale Hills catchment
Summary
Identification and prediction of soil moisture patterns are essential in a wide range of agronomic, hydrological, pedological, and environmental studies [3,4]. It is challenging to obtain accurate information on soil moisture at appropriate temporal and spatial scales [5,6]. Water 2020, 12, 2919 of information has impeded the modeling, prediction, and management of water resources [7,8,9,10]. Previous studies have indicated that the spatial pattern of soil moisture is highly dependent on various controlling factors such as parent material, soil, land use/vegetation, topography, and climate [1,8,15,16] Linking soil moisture mapping with monitoring can provide a more integrated approach to amplify the information on soil moisture in understanding soils and water resources [11,12,13] and provides a way of combatting the general decline of field hydrology relative to modeling [14].
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