Add to ORKGSeagrass meadows are primary producers that provide important ecosystem services, such as improved water quality, sediment stabilisation and trapping and recycling of nutrients. Most of these ecological services are strongly influenced by the vertical exchange of water across the canopy-water interface. That is, vertical mixing is the main hydrodynamic process governing the large-scale ecological and environmental impact of seagrass meadows. The majority of studies into mixing in vegetated flows have focused on steady flow environments whereas many coastal canopies are subjected to oscillatory flows driven by surface waves. It is known that the rate of mass transfer will vary greatly between unidirectional and oscillatory flows, necessitati...
The systematic creation of gaps within canopies results in fragmentation and the architecture of fra...
Laboratory experiments measured the velocity inside a model meadow of submerged, flexible vegetation...
© The Author(s), 2016. This article is distributed under the terms of the Creative Commons Attributi...
Physical modeling of canopy‐flow interactions has mostly employed rigid model vegetation, whereby th...
Physical modelling of vegetated flows is an essential component of process -based investigations int...
Aquatic vegetation canopies, including seagrasses, provide a host of ecosystem services within coast...
Seagrasses develop extensive or patchy underwater meadows in coastal areas around the world, forming...
Estuaries are extensive habitats that are vulnerable to rising sea levels; a detailed understanding ...
Hydrodynamic processes are an important agent of stress and facilitation in seagrass meadows, but li...
[[abstract]]Vegetation canopies control mean and turbulent flow structure as well as surface wave pr...
This paper summarizes recent advances in vegetation hydrodynamics and uses the new concepts to explo...
Hydrodynamic processes are an important agent of stress and facilitation in seagrass meadows, but li...
Submerged aquatic vegetation can dramatically alter the drag, turbulence and diffusivity characteris...
The distinct turbulence dynamics and transport modulated by a common seagrass species were investiga...
The systematic creation of gaps within canopies results in fragmentation and the architecture of fra...
The systematic creation of gaps within canopies results in fragmentation and the architecture of fra...
Laboratory experiments measured the velocity inside a model meadow of submerged, flexible vegetation...
© The Author(s), 2016. This article is distributed under the terms of the Creative Commons Attributi...
Physical modeling of canopy‐flow interactions has mostly employed rigid model vegetation, whereby th...
Physical modelling of vegetated flows is an essential component of process -based investigations int...
Aquatic vegetation canopies, including seagrasses, provide a host of ecosystem services within coast...
Seagrasses develop extensive or patchy underwater meadows in coastal areas around the world, forming...
Estuaries are extensive habitats that are vulnerable to rising sea levels; a detailed understanding ...
Hydrodynamic processes are an important agent of stress and facilitation in seagrass meadows, but li...
[[abstract]]Vegetation canopies control mean and turbulent flow structure as well as surface wave pr...
This paper summarizes recent advances in vegetation hydrodynamics and uses the new concepts to explo...
Hydrodynamic processes are an important agent of stress and facilitation in seagrass meadows, but li...
Submerged aquatic vegetation can dramatically alter the drag, turbulence and diffusivity characteris...
The distinct turbulence dynamics and transport modulated by a common seagrass species were investiga...
The systematic creation of gaps within canopies results in fragmentation and the architecture of fra...
The systematic creation of gaps within canopies results in fragmentation and the architecture of fra...
Laboratory experiments measured the velocity inside a model meadow of submerged, flexible vegetation...
© The Author(s), 2016. This article is distributed under the terms of the Creative Commons Attributi...