Nonstationarity in threshold response of stormflow in southern Appalachian headwater catchments

Threshold behavior of stormflow response is an emergent pattern observed in several studies demonstrating subsurface storage controls on catchment rainfall‐runoff dynamics. These studies demonstrate a distinct transition from negligible stormflow discharge response to rapid, linearly increasing stor...

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Bibliographic Details
Published in:Water resources research 2017-08, Vol.53 (8), p.6579-6596
Main Authors: Scaife, Charles I., Band, Lawrence E.
Format: Article
Language:English
Subjects:
Annual variations
Atmospheric precipitations
Canopies
Canopy
Catchment area
Catchments
Climate
Climate and vegetation
Cloud-climate relationships
Complexity
Dormancy
Dynamics
Forest canopy
Forests
Geophysics
Growing season
Headwater catchments
Headwaters
hydroclimate variability
Hydrology
Interactions
Interannual variability
long‐term analysis
Moisture index
nonstationarity
Precipitation
Properties
Rain
Rainfall
Rainfall-runoff relationships
Regression analysis
Runoff
Seasons
Soil
Soil investigations
Soil moisture
stormflow generation
Stream discharge
Stream flow
threshold response
Thresholds
Variability
Water stress
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Summary:Threshold behavior of stormflow response is an emergent pattern observed in several studies demonstrating subsurface storage controls on catchment rainfall‐runoff dynamics. These studies demonstrate a distinct transition from negligible stormflow discharge response to rapid, linearly increasing stormflow identified by a single, uniquely defined threshold as a basic catchment attribute that relates to geophysical properties. Utilizing precipitation, streamflow, and soil moisture data spanning 15 years from three catchments at the Coweeta Hydrologic Laboratory (CHL), we analyze how threshold behavior forms and varies at several timescales. We pose three hypotheses: (1) stormflow thresholds form at CHL as a function of antecedent soil moisture and gross precipitation, (2) thresholds vary seasonally and interannually, and (3) threshold variation through time implies greater long‐term complexity of runoff controls beyond catchment geophysical properties, including forest canopy ecohydrologic feedbacks. We isolate threshold behavior of stormflow using piecewise regression analysis in short to long‐term data sets with respect to antecedent soil moisture index and gross precipitation. We use this to investigate threshold variation over seasonal, interannual, and decadal timescales that encompass hydroclimatic extremes. Seasonal analysis reveals that thresholds are more variable between growing seasons than between dormant seasons. In growing seasons with greater water stress, stormflow thresholds are lower after controlling for soil moisture storage suggesting more complex, long‐term rainfall‐runoff relationships as a result of forest canopy response to water stress. We present a conceptual model of how vegetation‐climate interactions influence long‐term rainfall‐runoff relationships creating interannual variability of stormflow thresholds and linear stormflow response. Key Points Stormflow thresholds as functions of combined precipitation and antecedent soil moisture exhibit seasonal and interannual nonstationarity Stormflow thresholds and linear response vary with recent climate dryness, ecosystem water use, and catchment geophysical properties Forest transpiration appears to “compete” for rooting zone soil moisture with shallow throughflow during drainage events
ISSN:0043-1397
1944-7973
DOI:10.1002/2017WR020376