Abstract
Feedbacks between woody plants and fluvial morphodynamics result in co-development of riparian vegetation communities and channel form. To advance mechanistic knowledge regarding these interactions, we measured the response of topography and flow to the presence of riparian tree seedlings with contrasting morphologies in an experimental, field-scale, meandering stream channel with a mobile sand bed. On a convex point bar, we installed seedlings of Tamarix spp. (tamarisk) and Populus fremontii (cottonwood) with intact roots and simulated a bankfull flood, with each of eight runs varying sediment supply, plant density, and plant species. Vegetation reduced turbulence and velocities on the bar relative to bare-bed conditions, inducing sediment deposition when vegetation was present, regardless of vegetation density or species. Sediment supply also played a dominant role, and eliminating sediment supply reduced deposition regardless of the presence of vegetation. Unexpectedly, plant density and species architecture (shrubby tamarisk versus single-stemmed cottonwood) had only a secondary influence on hydraulics and sediment transport. In the absence of plants, mobile bedforms were prominent across the bar, but vegetation of all types decreased the height and lateral extent of bedforms migrating across the bar, suggesting a mechanism by which vegetation modulates feedbacks among sediment transport, topography, and hydraulics. Our measurements and resulting insights bridge the gap between laboratory conditions and real dryland sand-bed rivers and motivate further morphodynamic modeling.
Highlights
Interacting physical and biological processes in river-floodplain systems shape ecosystems and channels (Naiman and Decamps, 1997; Gurnell, 2014; Politti et al, 2018)
The measurement phase of each experimental run occurred after the middle meander bend had finished topographic adjustment to imposed changes in sediment supply, but the reach as a whole exhibited reach-scale variability in sediment output, and sediment storage, among runs
Eliminating the sediment supply during Runs 5–7 did not result in an immediate reduction in sediment flux exiting the downstream end of the experimental stream, suggesting continued mobilization of sand stored during the previous runs
Summary
Interacting physical and biological processes in river-floodplain systems shape ecosystems and channels (Naiman and Decamps, 1997; Gurnell, 2014; Politti et al, 2018). Flood and sedimentation history influence plant mortality (Wilcox and Shafroth, 2013; Bywater-Reyes et al, 2015), the cohort structure of riparian tree populations, and the successional trajectory of vegetation communities (Scott et al, 1996; Balian and Naiman, 2005; Birken and Cooper, 2006; Stella et al, 2011). The spread of cottonwood can pose management challenges: for example, cottonwood (Populus deltoides) encroachment following damming along the Platte River, NE has been countered by active tree clearing in an attempt to restore open channel habitat for migratory birds along the formerly wide, shallow braided river (Johnson, 1994; Platte River Recovery Implementation Program, 2006)
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