4.7 Article

Quantifying Hydraulic Roughness From Field Data: Can Dune Morphology Tell the Whole Story?

期刊

WATER RESOURCES RESEARCH
卷 57, 期 12, 页码 -

出版社

AMER GEOPHYSICAL UNION
DOI: 10.1029/2021WR030329

关键词

river dunes; hydraulic roughness; field data; friction factor

资金

  1. Netherlands Organisation for Scientific Research (NWO) [NWO-TTW 17062]

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This study analyzed hydraulic roughness of the Rhine and Waal rivers in the Netherlands based on dune geometry and topographic data. Results showed that even dune geometry could not fully explain roughness variations, and multi-kilometer depth oscillations may play a significant role in causing roughness. Further research is needed to understand the implications of depth variations on flow resistance.
Hydraulic roughness is a fundamental property in river research, as it directly affects water levels, flow strength and the associated sediment transport rates. However, quantification of roughness is challenging, as it is not directly measurable in the field. In lowland rivers, bedforms are a major source of hydraulic roughness. Decades of research have focused on dunes to allow parameterization of roughness, with relatively little focus on field verification. This study aims to establish the predictive capacity of current roughness predictors, and to identify reasons for the unexplained part of the variance in roughness. We quantified hydraulic roughness based on the Darcy-Weisbach friction factor (f) calculated from hydraulic field data of a 78 km-long trajectory of the river Rhine and river Waal in the Netherlands. This is compared to predicted roughness values based on dune geometry, and to the spatial trends in the local topographic leeside angle, both inferred from bathymetric field data. Results from both approaches show the same general trend and magnitude of roughness values (0.019 f < 0.069). Roughness inferred from dune geometry explains at best 31% of the variance. Efforts to explain the remaining variance from statistics of the local topographic leeside angles, which supposedly control flow separation, were unsuccessful. Unexpectedly, multi-kilometer depth oscillations explain 34% of the total roughness variations. We suggest that flow divergence associated with depth increase causes energy loss, which is reflected in an elevated hydraulic roughness. Multi-kilometer depth variations occur in many rivers worldwide, which implies a cause of flow resistance that needs further study.

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