Add to ORKGThe study of free-surface flows over vegetative structures presents a challenging setting for theoretical, computational and experimental analysis. In this work, we develop a multiple-scales asymptotic framework for the evolution of free-surface waves over rigid vegetation and a slowly varying substrate. The analysis quantifies the balance between the competing effects of vegetation and shoaling, and provides a prediction of the amplitude as the wave approaches a coastline. Our analysis unifies and extends existing theories that study these effects individually. The asymptotic predictions are shown to provide good agreement with full numerical simulations (varying depth) and published experimental results (constant depth)
We study long-wave evolution and runup on piecewise linear one- and two-dimensional bathymetries ana...
Laboratory experiments were carried out to study the flow structure both inside and above different ...
Graduation date: 2015The understanding and prediction how coastal wetland vegetation attenuates wave...
The study of free-surface flows over vegetative structures presents a challenging setting for theore...
This thesis is concerned with the mechanical aspects of fluid-vegetation interaction in coastal flow...
We study the effects of emergent coastal forests on the propagation of long surface waves of small a...
Surface wave interaction with aquatic vegetation appears to play a key role in coastal hydro-morpho-...
Aquatic vegetation attenuates local currents, dampens wave energy and promotes sedimentation. Its fu...
[[abstract]]Vegetation canopies control mean and turbulent flow structure as well as surface wave pr...
Aquatic vegetation provides ecosystem services of great value, including the damping of waves, which...
Abstract This paper explores several asymptotic limit regimes for shallow water flows over multiscal...
A multi-scale asymptotic theory is derived for the evolution and interaction of currents and surface...
Abstract Ecosystems threatened by climate change can boost their resilience by developing spatial pa...
Dissipation of waves propagating through natural salt marsh vegetation was about half the dissipatio...
An understanding of extreme waves is important in the design and analysis of offshore structures, su...
We study long-wave evolution and runup on piecewise linear one- and two-dimensional bathymetries ana...
Laboratory experiments were carried out to study the flow structure both inside and above different ...
Graduation date: 2015The understanding and prediction how coastal wetland vegetation attenuates wave...
The study of free-surface flows over vegetative structures presents a challenging setting for theore...
This thesis is concerned with the mechanical aspects of fluid-vegetation interaction in coastal flow...
We study the effects of emergent coastal forests on the propagation of long surface waves of small a...
Surface wave interaction with aquatic vegetation appears to play a key role in coastal hydro-morpho-...
Aquatic vegetation attenuates local currents, dampens wave energy and promotes sedimentation. Its fu...
[[abstract]]Vegetation canopies control mean and turbulent flow structure as well as surface wave pr...
Aquatic vegetation provides ecosystem services of great value, including the damping of waves, which...
Abstract This paper explores several asymptotic limit regimes for shallow water flows over multiscal...
A multi-scale asymptotic theory is derived for the evolution and interaction of currents and surface...
Abstract Ecosystems threatened by climate change can boost their resilience by developing spatial pa...
Dissipation of waves propagating through natural salt marsh vegetation was about half the dissipatio...
An understanding of extreme waves is important in the design and analysis of offshore structures, su...
We study long-wave evolution and runup on piecewise linear one- and two-dimensional bathymetries ana...
Laboratory experiments were carried out to study the flow structure both inside and above different ...
Graduation date: 2015The understanding and prediction how coastal wetland vegetation attenuates wave...