Run‐off processes from mountains to foothills: The role of soil stratigraphy and structure in influencing run‐off characteristics across high to low relief landscapes

The critical zone features that control run‐off generation, specifically at the regional watershed scale, are not well understood. Here, we addressed this knowledge gap by quantitatively and conceptually linking regional watershed‐scale run‐off regimes with critical zone structure and climate gradie...

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Bibliographic Details
Published inHydrological processes Vol. 32; no. 11; pp. 1546 - 1560
Main Authors Zimmer, Margaret A., Gannon, John P.
Format Journal Article
LanguageEnglish
Published Chichester Wiley Subscription Services, Inc 30.05.2018
Subjects
Architecture
baseflow
Coefficients
Correlation coefficient
Correlation coefficients
critical zone
Discharge measurement
Foothills
Gaging stations
Geological surveys
Hydrologic models
Hydrologic processes
Hydrology
Landscape
Mountains
Physiographic provinces
Precipitation
Provinces
Rainfall
regional watershed
Regolith
Regression analysis
Regression models
run‐off
Soil
Soil depth
Soil structure
storage
Stratigraphy
Surveying
Terrestrial environments
Watersheds
United States > US
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Summary:The critical zone features that control run‐off generation, specifically at the regional watershed scale, are not well understood. Here, we addressed this knowledge gap by quantitatively and conceptually linking regional watershed‐scale run‐off regimes with critical zone structure and climate gradients across two physiographic provinces in the Southeastern United States. We characterized long‐term (~20 years) discharge and precipitation regimes for 73 watersheds with United States Geological Survey in‐stream gaging stations across the Appalachian Mountain and Piedmont physiographic provinces of North Carolina. Watersheds included in this analysis had <10% developed land and ranged in size from 14.1–4,390 km2. Thirty‐four watersheds were located in the Piedmont physiographic province, which is typically classified as a low relief landscape with deep, highly weathered soils and regolith. Thirty‐nine watersheds were located in the Appalachian Mountain physiographic province, which is typically classified as a steeper landscape with highly weathered, but shallower soils and regolith. From the United States Geological Survey daily mean run‐off time series, we calculated annual and seasonal baseflow indices (BFI), minimum, mean, and maximum daily run‐off, and Pearson's correlation coefficients between precipitation and baseflow. Our results showed that Appalachian Mountain watersheds systematically had higher minimum daily flows and BFI values. Piedmont watersheds displayed much larger deviations from mean annual BFI in response to year‐to‐year variability in precipitation. A series of linear regression models between 21 landscape metrics and annual BFIs showed non‐linear and complex terrestrial–hydrological relationships across the two provinces. From these results, we discuss how distinct features of critical zone architecture, with specific focus on soil depth and stratigraphy, may be dominating the regulation of hydrological processes and run‐off regimes across these provinces.
ISSN:0885-6087
1099-1085
DOI:10.1002/hyp.11488