An experimental study of drainage network development by surface and subsurface flow in low-gradient landscapes
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Published:2022-06-10
Issue:3
Volume:10
Page:581-603
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ISSN:2196-632X
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Container-title:Earth Surface Dynamics
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language:en
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Short-container-title:Earth Surf. Dynam.
Author:
Sockness Brian G., Gran Karen B.ORCID
Abstract
Abstract. How do channel networks develop in low-gradient, poorly drained landscapes? Rivers form elaborate drainage networks with morphologies that express the unique environments in which they developed, yet we lack an understanding of what drives channel development in low-gradient landscapes like those left behind in the wake of continental glaciation. To better understand what controls the erosional processes allowing channel growth and integration of surface water non-contributing areas (NCAs) over time, we conducted a series of experiments in a small-scale drainage basin. By varying substrate and precipitation, we could vary the partitioning of flow between the surface and subsurface, impacting erosional processes. Two different channel head morphologies developed, interpreted as channel growth via overland flow and seepage erosion. Channel growth was dominated by overland flow vs. seepage erosion depending on substrate composition, rainfall rate, and drainage basin relief. Seepage-driven erosion was favored in substrates with higher infiltration rates, whereas overland flow was more dominant in experiments with high precipitation rates, although both processes occurred in all runs. Overland flow channels formed at the onset of experiments and expanded over a majority of the basin area, forming broad dendritic networks. Large surface water contributing areas (CAs) supported numerous first-order channels, allowing for more rapid integration of NCAs than through seepage erosion. When overland flow was the dominant process, channels integrated NCAs at a similar, consistent rate under all experimental conditions. Seepage erosion began later in experiments after channels had incised enough for exfiltrating subsurface flow to initiate mass wasting of headwalls. Periodic mass wasting of channel heads caused them to assume an amphitheater-shaped morphology. Seepage allowed for channel heads to expand with smaller surface water CAs than overland flow channels, allowing for network expansion to continue even with low surface CAs. Seepage-driven channel heads integrated NCAs more slowly than channel heads dominated by overland flow, but average erosion rates in channels extending through seepage erosion were higher. The experimental results provide insight into drainage networks that formed throughout areas affected by continental glaciation, and highlight the importance of subsurface hydrologic connections in integrating and expanding drainage networks over time in these low-gradient landscapes.
Funder
National Science Foundation
Publisher
Copernicus GmbH
Subject
Earth-Surface Processes,Geophysics
Reference101 articles.
1. Abotalib, A. Z., Sultan, M., and Elkadiri, R.: Groundwater processes in Saharan Africa: Implications for landscape evolution in arid environments, Earth-Science Rev., 156, 108–136, https://doi.org/10.1016/j.earscirev.2016.03.004, 2016. 2. Abrams, D. M., Lobkovsky, A. E., Petroff, A. P., Straub, K. M., McElroy, B., Mohrig, D. C., Kudrolli, A., and Rothman, D. H.: Growth laws for channel networks incised by groundwater flow, Nat. Geosci., 2, 193–196, https://doi.org/10.1038/ngeo432, 2009. 3. Altin, T. B. and Altin, B. N.: Development and morphometry of drainage nnetwork in volcanic terrain, Central Anatolia, Turkey, Geomorphology, 125, 485–503, https://doi.org/10.1016/j.geomorph.2010.09.023, 2011. 4. Babault, J., Van Den Driessche, J., and Teixell, A.: Longitudinal to transverse drainage network evolution in the High Atlas (Morocco): The role of tectonics, Tectonics, 31, 1–15, https://doi.org/10.1029/2011TC003015, 2012. 5. Berhanu, M., Petroff, A., Devauchelle, O., Kudrolli, A., and Rothman, D. H.: Shape and dynamics of seepage erosion in a horizontal granular bed, Phys. Rev. E, 86, 1–9, https://doi.org/10.1103/PhysRevE.86.041304, 2012.
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