Abstract
This is Part I of two papers on man-induced regime shifts in small, narrow, and converging estuaries, with focus on the interaction between effective hydraulic drag, fine sediment import, and tidal amplification, induced by river engineering works, e.g., narrowing and deepening. In this part, a simple linear analytical model is derived, solving the linearized shallow water equations in exponentially converging tidal rivers. Distinguishing reflecting and non-reflecting conditions, a non-dimensional dispersion equation is derived which yields the real and imaginary wave numbers as a function of the estuarine convergence number and effective hydraulic drag. The estuarine convergence number describes the major geometrical features of a tidal river, e.g., intertidal area, convergence length, and water depth. This model is used in Part II analyzing the historical development of the tide in four rivers. Part I also presents a conceptual model on the response of tidal rivers to narrowing and deepening. It is argued that, upon the loss of intertidal area, flood-dominant conditions prevail, upon which fine sediments are pumped into the river, reducing its effective hydraulic drag. Then a snowball effect may be initiated, bringing the river into a hyper-turbid state. This state is self-maintaining because of entrainment processes, and favorable from an energetic point of view, and therefore highly stable. We may refer to an alternative steady state.
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Acknowledgments
This work was carried within the framework of the LTV project, which is the acronym for Long-Term Vision of Scheldt estuary with respect to Safety, Accessibility, and Nature, in which the following sub-projects are integrated: Maintaining fairways Scheldt estuary, Permits for disposal of dredged sediments, and the so-called KPP (knowledge of primary processes) program of Rijkswaterstaat. The study was financed by the Flemish “Afdeling Maritieme Toegang” (Maritime Department) and Rijkswaterstaat, Waterdienst, and Directorate Zeeland (the Dutch Ministry of Infrastructure and Environment). The subject of the research in this paper was formulated by Mr. Youri Meersschaut requesting the analysis of the fine sediment dynamics in the Scheldt River. Further, we like to thank Mr. Cees Kuijper and Dr. Henk Schuttelaars for their many constructive comments and ongoing discussions on this subject, and Dr. Tom de Mulder for reviewing a report of this study. We also would like to acknowledge the help of Mr. Marcel Taal in organizing and coordinating our study.
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Responsible Editor: Rockwell Geyer
This article is part of the Topical Collection on Physics of Estuaries and Coastal Seas 2012
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Winterwerp, J.C., Wang, Z.B. Man-induced regime shifts in small estuaries—I: theory. Ocean Dynamics 63, 1279–1292 (2013). https://doi.org/10.1007/s10236-013-0662-9
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DOI: https://doi.org/10.1007/s10236-013-0662-9