Coarse graining of (geophysical) flow problems is a necessity brought upon us by the wide range of spatial and temporal scales present in these problems, which cannot be all represented on a numerical grid without an inordinate amount of computational resources. Traditionally, the effect of the unresolved eddies is approximated by deterministic closure models, i.e. so-called parameterizations. The effect of the unresolved eddy field enters the resolved-scale equations as a forcing term, denoted as the’eddy forcing’. Instead of creating a deterministic parameterization, our goal is to infer a stochastic, data-driven surrogate model for the eddy forcing from a (limited) set of reference data, with the goal of accurately capturing the long-ter...
If unstructured meshes are refined to locally represent eddy dynamics in ocean circulation models, a...
The role of mesoscale eddies is crucial for the ocean circulation and its energy budget. The sub-gri...
Turbulence in the ocean dominates the vertical movement of heat and salt, as well as chemical and bi...
This study makes progress towards a data-driven parameterization for mesoscale oceanic eddies. To de...
The large-scale ocean circulation is strongly influenced by mesoscale turbulent eddies. Mesoscale oc...
The problem of augmenting low-resolution ocean circulation models with the information extracted fro...
The multiscale variability of the ocean circulation due to its nonlinear dynamics remains a big chal...
The problem of defining oceanic mesoscale eddies remains generally unresolved because there is no un...
We present a comprehensive study of the mesoscale eddy forcing in the ocean by proposing spatially l...
This study is motivated by the need to develop stochastic parameterisations for representing the eff...
Accurate representation of large-scale flow patterns in low-resolution ocean simulations is one of t...
In climate simulations, the impacts of the subgrid scales on the resolved scales are conventionally ...
International audienceAbstract We present a simple parameterization for coarse-resolution ocean mode...
This thesis aims to provide a comprehensive analysis of multi-scale oceanic variabilities using vari...
This work continues development of dynamically consistent parameterizations for representing mesosca...
If unstructured meshes are refined to locally represent eddy dynamics in ocean circulation models, a...
The role of mesoscale eddies is crucial for the ocean circulation and its energy budget. The sub-gri...
Turbulence in the ocean dominates the vertical movement of heat and salt, as well as chemical and bi...
This study makes progress towards a data-driven parameterization for mesoscale oceanic eddies. To de...
The large-scale ocean circulation is strongly influenced by mesoscale turbulent eddies. Mesoscale oc...
The problem of augmenting low-resolution ocean circulation models with the information extracted fro...
The multiscale variability of the ocean circulation due to its nonlinear dynamics remains a big chal...
The problem of defining oceanic mesoscale eddies remains generally unresolved because there is no un...
We present a comprehensive study of the mesoscale eddy forcing in the ocean by proposing spatially l...
This study is motivated by the need to develop stochastic parameterisations for representing the eff...
Accurate representation of large-scale flow patterns in low-resolution ocean simulations is one of t...
In climate simulations, the impacts of the subgrid scales on the resolved scales are conventionally ...
International audienceAbstract We present a simple parameterization for coarse-resolution ocean mode...
This thesis aims to provide a comprehensive analysis of multi-scale oceanic variabilities using vari...
This work continues development of dynamically consistent parameterizations for representing mesosca...
If unstructured meshes are refined to locally represent eddy dynamics in ocean circulation models, a...
The role of mesoscale eddies is crucial for the ocean circulation and its energy budget. The sub-gri...
Turbulence in the ocean dominates the vertical movement of heat and salt, as well as chemical and bi...