Extending the canopy flow model for natural, highly flexible macrophyte canopies
Details
Serval ID
serval:BIB_63ECEF29E6FA
Type
Inproceedings: an article in a conference proceedings.
Collection
Publications
Institution
Title
Extending the canopy flow model for natural, highly flexible macrophyte canopies
Title of the conference
River Flow 2014
Publisher
CRC Press
Organization
Swiss Fed Off Environm; BG Consulting Engineers; Hydro Exploitat SA; E dric ch; IM & IUB Engn; Basler & Hofmann; AquaVis Engn; Met Flow SA; Int Assoc Hydro Environm Engn & Res, Comm Fluvial Hydraul; Stucky; Groupe E; Patscheider Partner; HydroCosmos SA; Kissling Zbinden AG; Ribi SA; Poyry; Swiss Assoc Water Management; Ecole Polytechnique Federale Lausanne, Lab Hydraul Construct
ISBN
978-1-4987-0442-7; 978-1-138-02674-2
Publication state
Published
Issued date
2014
Editor
Schleiss A.J., DeCesare G., Franca M.J., Pfister M.
Pages
509-516
Language
english
Notes
7th International Conference on Fluvial Hydraulics (River Flow), Ecole Polytechnique Federale Lausanne, Lausanne, SWITZERLAND, SEP 03-05, 2014
Abstract
Flow structures above vegetation canopies have received much attention
within terrestrial and aquatic literature. This research has led to a
good process understanding of mean and turbulent canopy flow structure.
However, much of this research has focused on rigid or semi-rigid
vegetation with relatively simple morphology. Aquatic macrophytes differ
from this form, exhibiting more complex morphologies, predominantly
horizontal posture in the flow and a different force balance. While some
recent studies have investigated such canopies, there is still the need
to examine the relevance and applicability of general canopy layer
theory to these types of vegetation. Here, we report on a range of
numerical experiments, using both semi-rigid and highly flexible
canopies. The results for the semi-rigid canopies support existing
canopy layer theory. However, for the highly flexible vegetation, the
flow pattern is much more complex and suggests that a new canopy model
may be required.
within terrestrial and aquatic literature. This research has led to a
good process understanding of mean and turbulent canopy flow structure.
However, much of this research has focused on rigid or semi-rigid
vegetation with relatively simple morphology. Aquatic macrophytes differ
from this form, exhibiting more complex morphologies, predominantly
horizontal posture in the flow and a different force balance. While some
recent studies have investigated such canopies, there is still the need
to examine the relevance and applicability of general canopy layer
theory to these types of vegetation. Here, we report on a range of
numerical experiments, using both semi-rigid and highly flexible
canopies. The results for the semi-rigid canopies support existing
canopy layer theory. However, for the highly flexible vegetation, the
flow pattern is much more complex and suggests that a new canopy model
may be required.
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Create date
13/03/2015 14:54
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20/08/2019 15:20
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