Solid particles (such as snow or sand) can get eroded and transported by the wind, and little understanding has been achieved in this domain. We propose a description of the phenomenon in terms of a cellular automata and lattice Boltzmann model. Numerical simulations show that plausible mechanisms are sufficient to explain a wide range of deposition patterns occurring at different space scales. In particular, we reproduce the so-called ripples, that is oscillations of the deposition surface for which no formation mechanism is clearly established
Simulating water behaviour in coastal areas is an important tool when predicting sedimentary process...
Erosion has a long history in science and is used in many different fields today, for example in geolo...
International audienceIn a real-space cellular automaton dune model, individual physical processes s...
Solid particles (such as snow or sand) can get eroded and transported by the wind, and little unders...
We consider a simple lattice gas model to simulate erosion, deposition and particle transport in a s...
The dynamics of snow erosion, transport and deposition due to the action of wind is still a controve...
Cellular automata (CA) and lattice Boltzmann (LB) approaches are computational methods that offer fl...
We present a lattice gas model to simulate snow transport by wind and its deposition on a given grou...
We simulate particles suspended in a fluid by means of the lattice-Boltzmann method and its extensio...
AbstractWe discuss the lattice Boltzmann computing approach, its connection with cellular automata a...
A simple stochastic cellular automaton model is proposed for ripples and dunes formation. Saltation...
International audienceDespite their very broad range of applications, fluid-grain interactions remai...
Lattice Boltzmann models have a remarkable ability to simulate single- and multi-phase fluids and tr...
Deposition of inertial solid particles transported by turbulent flows is modelled in a framework of ...
Field observations and laboratory experiments have shown that ash sedimentation can be significantly...
Simulating water behaviour in coastal areas is an important tool when predicting sedimentary process...
Erosion has a long history in science and is used in many different fields today, for example in geolo...
International audienceIn a real-space cellular automaton dune model, individual physical processes s...
Solid particles (such as snow or sand) can get eroded and transported by the wind, and little unders...
We consider a simple lattice gas model to simulate erosion, deposition and particle transport in a s...
The dynamics of snow erosion, transport and deposition due to the action of wind is still a controve...
Cellular automata (CA) and lattice Boltzmann (LB) approaches are computational methods that offer fl...
We present a lattice gas model to simulate snow transport by wind and its deposition on a given grou...
We simulate particles suspended in a fluid by means of the lattice-Boltzmann method and its extensio...
AbstractWe discuss the lattice Boltzmann computing approach, its connection with cellular automata a...
A simple stochastic cellular automaton model is proposed for ripples and dunes formation. Saltation...
International audienceDespite their very broad range of applications, fluid-grain interactions remai...
Lattice Boltzmann models have a remarkable ability to simulate single- and multi-phase fluids and tr...
Deposition of inertial solid particles transported by turbulent flows is modelled in a framework of ...
Field observations and laboratory experiments have shown that ash sedimentation can be significantly...
Simulating water behaviour in coastal areas is an important tool when predicting sedimentary process...
Erosion has a long history in science and is used in many different fields today, for example in geolo...
International audienceIn a real-space cellular automaton dune model, individual physical processes s...