Abstract
Abstract. The controls on the spatial distribution of soil moisture include static and dynamic variables. The superposition of static and dynamic controls can lead to different soil moisture patterns for a given catchment during wetting, draining, and drying periods. These relationships can be further complicated in snow-dominated mountain regions where soil water input by precipitation is largely dictated by the spatial variability of snow accumulation and melt. In this study, we assess controls on spatial and temporal soil moisture variability in a small (0.02 km2), snow-dominated, semi-arid catchment by evaluating spatial correlations between soil moisture and site characteristics through different hydrologic seasons. We assess the relative importance of snow with respect to other catchment properties on the spatial variability of soil moisture and track the temporal persistence of those controls. Spatial distribution of snow, distance from divide, soil texture, and soil depth exerted significant control on the spatial variability of moisture content throughout most of the hydrologic year. These relationships were strongest during the wettest period and degraded during the dry period. As the catchment cycled through wet and dry periods, the relative spatial variability of soil moisture tended to remain unchanged. We suggest that the static properties in complex terrain (slope, aspect, soils) impose first order controls on the spatial variability of snow and resulting soil moisture patterns, and that the interaction of dynamic (timing of water input) and static influences propagate that relative constant spatial variability through most of the hydrologic year. The results demonstrate that snow exerts significant influence on how water is retained within mid-elevation semi-arid catchments and suggest that reductions in annual snowpacks associated with changing climate regimes may strongly influence spatial and temporal soil moisture patterns and catchment physical and biological processes.
Highlights
Soil moisture exists at a critical nexus between atmospheric and terrestrial hydrologic processes
Snow accumulation (Fig. 2b) and snow water equivalent during this study were generally greater in the southwest and central portions of the catchment, with some drifts forming on leeward sides of small seep channels
We have shown that spatial distribution of snow, along with slope position, soil texture, and soil depth, has significant control on the spatial variability of moisture content throughout most of the hydrologic year
Summary
Soil moisture exists at a critical nexus between atmospheric and terrestrial hydrologic processes. It occurs as a balance between the competing demands of the atmosphere, vegetation, and gravitational drainage. The spatial and temporal distribution of soil moisture controls numerous catchment processes including runoff generation, groundwater recharge, evapotranspiration, soil respiration, and biological productivity. Understanding the controls on the spatial and temporal variability of soil moisture is an essential step towards developing improved predictive models of catchment processes. A challenge is that the controls on the spatial distribution of soil moisture are combinations of static (e.g. topography, soil properties) and dynamic (e.g. precipitation, antecedent moisture) variables (Reynolds, 1970). Famiglietti et al (2008) summarized numerous studies illustrating how the spatial variability of soil moisture can increase or decrease with the spatial mean moisture content depending
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