Add to ORKGIn this paper, we develop and validate a rigorous modeling framework, based on Duhamel\u27s Theorem, for the unsteady one‐dimensional vertical transport of a solute across a flat sediment‐water interface (SWI) and through the benthic biolayer of a turbulent stream. The modeling framework is novel in capturing the two‐way coupling between evolving solute concentrations above and below the SWI and in allowing for a depth‐varying diffusivity. Three diffusivity profiles within the sediment (constant, exponentially decaying, and a hybrid model) are evaluated against an extensive set of previously published laboratory measurements of turbulent mass transfer across the SWI. The exponential diffusivity profile best represents experimental observati...
We link specific mechanisms of biogenous sediment mixing with the commonly used bioturbation coeffic...
Biological mixing in deep‐sea sediments is described in terms of a time‐dependent eddy diffusion mod...
The long-term goal of our research program is to understand, using laboratory experiments, numerical...
In this paper, we develop and validate a rigorous modeling framework, based on Duhamel’s Theorem, fo...
Many water quality and ecosystem functions performed by streams occur in the benthic biolayer, the b...
In aquatic environments, the benthic boundary layer (BBL) is the transition zone for dissolved solut...
The thesis focuses on the transport and transformation of nutrients and oxygen across the benthic bo...
Dissolved oxygen (DO) transfer between bottom sediments and the overlaying water (Water-Sediment In...
The thesis focuses on the transport and transformation of nutrients and oxygen across the benthic bo...
A simple, steady state, reaction-diffusion diagenesis model is used to quantify the possible error a...
Bioturbation in aquatic sediments results from many different biological activities, inducing parti...
Modeling mass-transfer across the sediment-water interface is a significant issue in environmental h...
International audienceUnderstanding diffusive processes across the sediment-water interface is impor...
The diffusive boundary layer (DBL) is a thin layer of fluid at the interface with a solid surface in...
AbstractBenthic oxygen dynamics and the exchange of oxygen and other solutes across the sediment‐wat...
We link specific mechanisms of biogenous sediment mixing with the commonly used bioturbation coeffic...
Biological mixing in deep‐sea sediments is described in terms of a time‐dependent eddy diffusion mod...
The long-term goal of our research program is to understand, using laboratory experiments, numerical...
In this paper, we develop and validate a rigorous modeling framework, based on Duhamel’s Theorem, fo...
Many water quality and ecosystem functions performed by streams occur in the benthic biolayer, the b...
In aquatic environments, the benthic boundary layer (BBL) is the transition zone for dissolved solut...
The thesis focuses on the transport and transformation of nutrients and oxygen across the benthic bo...
Dissolved oxygen (DO) transfer between bottom sediments and the overlaying water (Water-Sediment In...
The thesis focuses on the transport and transformation of nutrients and oxygen across the benthic bo...
A simple, steady state, reaction-diffusion diagenesis model is used to quantify the possible error a...
Bioturbation in aquatic sediments results from many different biological activities, inducing parti...
Modeling mass-transfer across the sediment-water interface is a significant issue in environmental h...
International audienceUnderstanding diffusive processes across the sediment-water interface is impor...
The diffusive boundary layer (DBL) is a thin layer of fluid at the interface with a solid surface in...
AbstractBenthic oxygen dynamics and the exchange of oxygen and other solutes across the sediment‐wat...
We link specific mechanisms of biogenous sediment mixing with the commonly used bioturbation coeffic...
Biological mixing in deep‐sea sediments is described in terms of a time‐dependent eddy diffusion mod...
The long-term goal of our research program is to understand, using laboratory experiments, numerical...