4.7 Article

Direct Observation of Hillslope Scale StorAge Selection Functions in Experimental Hydrologic Systems: Geomorphologic Structure and Preferential Discharge of Old Water

Journal

WATER RESOURCES RESEARCH
Volume 58, Issue 3, Pages -

Publisher

AMER GEOPHYSICAL UNION
DOI: 10.1029/2020WR028959

Keywords

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Funding

  1. National Science Foundation [EAR-1344552, EAR-1417175]
  2. Philecology Foundation of Fort Worth Texas
  3. Office of the Vice President of Research at the University of Arizona
  4. Technology and Research Initiative Fund (TRIF) Water, Environmental, and Energy Solutions (WEES) initiative at the University of Arizona (Shared Equipment Enhancement Funds)

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This study presents the time-variable transit time distributions and StorAge Selection (SAS) functions for understanding the water transport dynamics at the hillslope scale. It reveals that older water is preferentially discharged than younger water, which can be explained by the relative importance of advective and diffusive water dynamics and the geomorphologic structure of the hillslopes.
Spatially integrated water transport dynamics at the hillslope scale have rarely been observed directly, and underlying physical mechanisms of those dynamics are poorly understood. We present time-variable transit time distributions and StorAge Selection (SAS) functions for a 28 days tracer experiment conducted at the Landscape Evolution Observatory, Biosphere 2, the University of Arizona, AZ, USA. The observed form of the SAS functions is concave, meaning that older water in the hillslope was preferentially discharged than younger water. The concavity is, in part, explained by the relative importance of advective and diffusive water dynamics and by the geomorphologic structure of the hillslopes. A simple numerical examination illustrates that, for straight plan-shaped hillslopes, the saturated zone SAS function is concave when the hillslope Peclet (Pe) number is large (and thus when the advective water dynamics are more pronounced). We also investigated the effect of hillslope planform geometry on the saturated zone SAS function using a model and found that the more convergent the plan shape is, the more concave the SAS function is. A numerical examination indicates that the unsaturated zone SAS function is concave for straight and convergent hillslopes when the soil thickness is uniform. The concavity of those subcomponent SAS functions signifies that the hillslope scale SAS function is concave for straight or convergent plan shape hillslopes when the hillslope Pe number is high.

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