Aquatic flow over a submerged vegetation canopy is a ubiquitous example of flow adjacent to a permeable medium. Aquatic canopy flows, however, have two important distinguishing features. Firstly, submerged vegetation typically grows in shallow regions. Consequently, the roughness sublayer, the region where the drag length scale of the canopy is dynamically important, can often encompass the entire flow depth. In such shallow flows, vortices generated by the inflectional velocity profile are the dominant mixing mechanism. Vertical transport across the canopy–water interface occurs over a narrow frequency range centered around f v (the frequency of vortex passage), with the vortices responsible for more than three-quarters of the interfaci...
Vegetation is a characteristic feature of shallow aquatic flows such as rivers, lakes and coastal wa...
Physical modelling of vegetated flows is an essential component of process -based investigations int...
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Civil and Environmental Engineering...
Submerged aquatic vegetation can dramatically alter the drag, turbulence and diffusivity characteris...
This review describes mean and turbulent flow and mass transport in the presence of aquatic vegetati...
This paper summarizes recent advances in vegetation hydrodynamics and uses the new concepts to explo...
Submerged vegetation commonly grows and plays a vital role in aquatic ecosystems, but it is also reg...
Physical modeling of canopy‐flow interactions has mostly employed rigid model vegetation, whereby th...
The shear layer at the top of a submerged canopy generates coherent vortices that control exchange b...
Thesis (S.M.)--Massachusetts Institute of Technology, Dept. of Civil and Environmental Engineering, ...
Water flows through submerged and emergent vegetation control the transport and deposition of sedime...
In contrast to free shear layers, which grow continuously downstream, shear layers generated by subm...
which permits unrestricted use, distribution, and reproduction in any medium, provided the original ...
Vegetation offers higher resistance to the flow as compared to the bed of the channel causing the ri...
The transport of fine sediment and organic matter plays an important role in the nutrient dynamics o...
Vegetation is a characteristic feature of shallow aquatic flows such as rivers, lakes and coastal wa...
Physical modelling of vegetated flows is an essential component of process -based investigations int...
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Civil and Environmental Engineering...
Submerged aquatic vegetation can dramatically alter the drag, turbulence and diffusivity characteris...
This review describes mean and turbulent flow and mass transport in the presence of aquatic vegetati...
This paper summarizes recent advances in vegetation hydrodynamics and uses the new concepts to explo...
Submerged vegetation commonly grows and plays a vital role in aquatic ecosystems, but it is also reg...
Physical modeling of canopy‐flow interactions has mostly employed rigid model vegetation, whereby th...
The shear layer at the top of a submerged canopy generates coherent vortices that control exchange b...
Thesis (S.M.)--Massachusetts Institute of Technology, Dept. of Civil and Environmental Engineering, ...
Water flows through submerged and emergent vegetation control the transport and deposition of sedime...
In contrast to free shear layers, which grow continuously downstream, shear layers generated by subm...
which permits unrestricted use, distribution, and reproduction in any medium, provided the original ...
Vegetation offers higher resistance to the flow as compared to the bed of the channel causing the ri...
The transport of fine sediment and organic matter plays an important role in the nutrient dynamics o...
Vegetation is a characteristic feature of shallow aquatic flows such as rivers, lakes and coastal wa...
Physical modelling of vegetated flows is an essential component of process -based investigations int...
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Civil and Environmental Engineering...