Fluvial system dynamics derived from distributed sediment budgets: perspectives from an uncertainty‐bounded application

The utility of sediment budget analysis is explored in revealing spatio‐temporal changes in the sediment dynamics and morphological responses of a fluvial system subject to significant human impacts during the recent Anthropocene. Sediment budgets require a data‐intensive approach to represent spati...

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Bibliographic Details
Published in:Earth surface processes and landforms 2018-05, Vol.43 (6), p.1335-1354
Main Authors: Downs, Peter W., Dusterhoff, Scott R., Leverich, Glen T., Soar, Philip J., Napolitano, Michael B.
Format: Article
Language:English
Subjects:
Agricultural watersheds
Anthropocene
Budgets
California
Catchment area
Catchment areas
Catchments
Channel erosion
Coastal inlets
Data
Data processing
Dynamics
Efflux
Erosion
Error analysis
fluvial geomorphology
Fluvial sediments
Geomorphology
History
Human influences
Mathematical models
Modelling
Morphology
Polls & surveys
Regulated rivers
River channels
Rivers
Routing
Sediment
sediment budget
Sediment dynamics
Sediment yield
Sediments
Storage
Surveys
System dynamics
Temporal variations
Topographic maps
Topographic surveys
Uncertainty
Uncertainty analysis
uncertainty assessment
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Summary:The utility of sediment budget analysis is explored in revealing spatio‐temporal changes in the sediment dynamics and morphological responses of a fluvial system subject to significant human impacts during the recent Anthropocene. Sediment budgets require a data‐intensive approach to represent spatially‐differentiated impacts adequately and are subject to numerous estimation uncertainties. Here, field and topographic surveys, historical data, numerical modelling and a representative‐area extrapolation method are integrated to construct a distributed, process‐based sediment budget that addresses historical legacy factors for the highly regulated Lagunitas Creek (213 km2), California, USA, for the period 1983–2008. Independent corroboration methods and error propagation analysis produce an uncertainty assessment unique to a catchment of this size. Current sediment yields of ~20 000 t a‐1 ± 6000 t a‐1 equate to unit rates of ~300 t km‐2 a‐1 ± 90 t km‐2 a‐1 over the effective sediment contributing area of 64 km2. This is comparable with yields associated with early Euro‐American settlement in the catchment, despite loss of sediment supply upstream of the two large dams. It occurs because ~57% of the sediment is now derived from incision‐related channel erosion. Further, the highly efficient routing of channel‐derived sediments in these incised channels suggests an efflux of 84% of contemporary sediment production, contrasting with the efflux of ≈10–30% reported for unregulated agricultural catchments. The results highlight that sediment budgets for regulated rivers must accommodate channel morphological responses to avoid significantly misrepresenting catchment yields, and that volumetric precision in sediment budgets may best be improved by repeat, spatially dense, channel cross‐section surveys. Human activities have impacted every aspect of the sediment dynamics of Lagunitas Creek (production, storage, transfer, rates of movement through storage), confirming that, while distributed sediment budgets are data demanding and subject to numerous error sources, the approach can provide valuable insights into Anthropocene fluvial geomorphology. Copyright © 2017 John Wiley & Sons, Ltd. The utility of an uncertainty‐bound sediment budget analysis is explored in revealing changes in the sediment dynamics of a dammed fluvial system. Unit yields of ~300 t km‐2 a‐1 are close to rates during initial land clearances because ~57% of the sediment is now derived from channel
ISSN:0197-9337
1096-9837
DOI:10.1002/esp.4319