Mantle convection is the principal control on the thermal and geological evolution of the Earth. Mantle convection modeling involves solution of the mass, momentum, and energy equations for a viscous, creeping, incompressible non-Newtonian fluid at high Rayleigh and Peclet numbers. Our goal is to conduct global mantle convection simulations that can resolve faulted plate boundaries, down to 1 km scales. However, uniform resolution at these scales would result in meshes with a trillion elements, which would elude even sustained petaflops supercomputers. Thus parallel adaptive mesh refinement and coarsening (AMR) is essential. We present RHEA, a new generation mantle convection code designed to scale to hundreds of thousands of c...
We have incorporated faults as plate margins into time-dependent mantle convection models by using a...
International audienceReconstructing convective flow in the Earth's mantle is a crucial issue for a ...
There are three distinct mechanisms which might give rise to convection in the Earth's mantle: Rayl...
Mantle convection is the principal control on the thermal and geological evolution of the Earth. Ma...
A new generation, parallel adaptive-mesh mantle convection code, Rhea, is described and benchmarked....
Mantle convection is the fundamental physical process within earth's interior responsible for the th...
Numerical modeling of mantle convection is challenging. Owing to the multiscale nature of mantle dy...
The thermal convection of rock in Earth's mantle and associated plate tectonics are modeled by nonli...
The Earth mantle convects on a global scale, coupling the stress field at every point to every other...
The long-term motion of the Earth's mantle is of considerable interest to geologists and geodynamist...
Plate tectonics is regulated by driving and resisting forces concentrated at plate boundaries, but o...
Mantle convection shapes Earth\u27s surface by generating dynamic topography. Observational constrai...
Abstract We report the current status of our numerical simulation code named “ACuTEMan ” for large-s...
AbstractThe periodic assembly and dispersal of continental fragments, referred to as the supercontin...
We have incorporated faults as plate margins into time-dependent mantle convection models by using a...
International audienceReconstructing convective flow in the Earth's mantle is a crucial issue for a ...
There are three distinct mechanisms which might give rise to convection in the Earth's mantle: Rayl...
Mantle convection is the principal control on the thermal and geological evolution of the Earth. Ma...
A new generation, parallel adaptive-mesh mantle convection code, Rhea, is described and benchmarked....
Mantle convection is the fundamental physical process within earth's interior responsible for the th...
Numerical modeling of mantle convection is challenging. Owing to the multiscale nature of mantle dy...
The thermal convection of rock in Earth's mantle and associated plate tectonics are modeled by nonli...
The Earth mantle convects on a global scale, coupling the stress field at every point to every other...
The long-term motion of the Earth's mantle is of considerable interest to geologists and geodynamist...
Plate tectonics is regulated by driving and resisting forces concentrated at plate boundaries, but o...
Mantle convection shapes Earth\u27s surface by generating dynamic topography. Observational constrai...
Abstract We report the current status of our numerical simulation code named “ACuTEMan ” for large-s...
AbstractThe periodic assembly and dispersal of continental fragments, referred to as the supercontin...
We have incorporated faults as plate margins into time-dependent mantle convection models by using a...
International audienceReconstructing convective flow in the Earth's mantle is a crucial issue for a ...
There are three distinct mechanisms which might give rise to convection in the Earth's mantle: Rayl...