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Controls From Above or Below? The Influence of Entangled Climate and Land Characteristics on Hydrological Dynamics in Headwater Catchments
  • +12
  • Devon Kerins,
  • Abigail S. Knapp,
  • Fiona S. Liu,
  • Valerie Smykalov,
  • Matthew P. Berzonsky,
  • Andrew Vierbircher,
  • Kayalvizhi Sadayappan,
  • Bryn Stewart,
  • Elizabeth M. Andrews,
  • Pamela Sullivan,
  • Holly Barnard,
  • Jan Seibert,
  • Lauren McPhillips,
  • Kamini Singha,
  • Li Li
Devon Kerins
The Pennsylvania State University

Corresponding Author:[email protected]

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Abigail S. Knapp
The Pennsylvania State University
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Fiona S. Liu
The Pennsylvania State University
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Valerie Smykalov
The Pennsylvania State University
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Matthew P. Berzonsky
The Pennsylvania State University
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Andrew Vierbircher
The Pennsylvania State University
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Kayalvizhi Sadayappan
The Pennsylvania State University
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Bryn Stewart
The Pennsylvania State University
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Elizabeth M. Andrews
The University of Texas at El Paso
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Pamela Sullivan
Oregon State University
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Holly Barnard
University of Colorado Boulder Department of Geography
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Jan Seibert
Universitat Zurich
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Lauren McPhillips
The Pennsylvania State University
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Kamini Singha
Colorado School of Mines
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Li Li
The Pennsylvania State University
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Abstract

Abstract Although the importance of dynamic water storage and flowpath partitioning on discharge behavior has been well recognized within the critical zone community, there is still little consensus surrounding the question, “ How do climate factors from above and land characteristics from below dictate dynamic storage, flowpath partitioning, and ultimately regulate hydrological dynamics?” Answers to this question have been hindered by limited and inconsistent spatio-temporal data and arduous-to-measure subsurface data. Here we aim to answer this question above by using a semi-distributed hydrological model (HBV model) to simulate and understand the dynamics of water storage, groundwater flowpaths, and discharge in 15 headwater catchments across the contiguous United States. Results show that topography, precipitation falling as snow, and catchment soil texture all influence catchment dynamic storage, storage-discharge sensitivity, flowpath partitioning, and discharge flashiness. Flat, rain-dominated sites (< 30% precipitation as snow) with finer soils exhibited flashier discharge regimes than catchments with coarse soils and/or significant snowfall (>30% precipitation as snow). Rain-dominated sites with clay soils (indicative of chemical weathering) showed lower dynamic storage and discharge that was more sensitive to changes in dynamic storage than rainy sites with coarse soils. Steep, snowy sites with coarse soils (more mechanical weathering) had lowest dynamic storage and deep groundwater fed discharge that was less sensitive to changes in dynamic storage than fine-soil snowy or rainy catchments. These results highlight aridity and precipitation (snow versus rain) as the dominant climate controls from above and topography and soil texture as the dominant land controls from below. The study challenges the traditional view that climate controls water balance while subsurface structure dictates subsurface flow path. Rather, it shows that climate and land characteristics jointly regulate water balance, groundwater flowpath partitioning, and discharge responses. These findings have important implication for the projection of the future of water resources, especially as climate change and human activities continue to intensify.
27 Sep 2024Submitted to Hydrological Processes
08 Oct 2024Submission Checks Completed
08 Oct 2024Assigned to Editor
12 Oct 2024Reviewer(s) Assigned
22 Oct 2024Reviewer(s) Assigned