none5We compare two different codes for simulations of cosmological structure formation to investigate the sensitivity of hydrodynamical instabilities to numerics, in particular, the hydro solver and the application of adaptive mesh refinement (AMR). As a simple test problem, we consider an initially spherical gas cloud in a wind, which is an idealized model for the merger of a subcluster or galaxy with a big cluster. Based on an entropy criterion, we calculate the mass stripping from the subcluster as a function of time. Moreover, the turbulent velocity field is analyzed with a multi-scale filtering technique. We find remarkable differences between the commonly used PPM solver with directional splitting in the Enzo code and an unsplit vari...
This thesis investigates the issues introduced by the advanced computing technologies applications t...
We present a detailed comparison between the well-known smoothed particle hydrodynamics (SPH) code g...
AbstractWe describe a powerful methodology for numerical solution of 3-D self-gravitational hydrodyn...
We examine how three fundamentally different numerical hydrodynamics codes follow the evolution of a...
Numerical simulations present a fundamental building block of our modern theoretical understanding o...
International audienceWe have explored the evolution of gas distributions from cosmological simulati...
A new N-body and hydrodynamical code, called RAMSES, is presented. It has been designed to study str...
A new N-body and hydrodynamical code, called RAMSES, is presented. It has been designed to study str...
In this thesis, we develop an adaptive mesh refinement (AMR) code including magnetic fields, and use...
Adaptive mesh refinement (AMR) is a technique that has been featured only sporadically in atmospheri...
Context. Colliding flows are a commonly used scenario for the formation of molecular clouds in nume...
Numerical effects are known to plague adaptive mesh refinement (AMR) codes when treating massive par...
Star formation is such a complex process that accurate numerical tools are needed to quantitatively ...
Star formation is such a complex process that accurate numerical tools are needed to quantitatively ...
We implemented sink particles in the Adaptive Mesh Refinement (AMR) code FLASH to model the gravitat...
This thesis investigates the issues introduced by the advanced computing technologies applications t...
We present a detailed comparison between the well-known smoothed particle hydrodynamics (SPH) code g...
AbstractWe describe a powerful methodology for numerical solution of 3-D self-gravitational hydrodyn...
We examine how three fundamentally different numerical hydrodynamics codes follow the evolution of a...
Numerical simulations present a fundamental building block of our modern theoretical understanding o...
International audienceWe have explored the evolution of gas distributions from cosmological simulati...
A new N-body and hydrodynamical code, called RAMSES, is presented. It has been designed to study str...
A new N-body and hydrodynamical code, called RAMSES, is presented. It has been designed to study str...
In this thesis, we develop an adaptive mesh refinement (AMR) code including magnetic fields, and use...
Adaptive mesh refinement (AMR) is a technique that has been featured only sporadically in atmospheri...
Context. Colliding flows are a commonly used scenario for the formation of molecular clouds in nume...
Numerical effects are known to plague adaptive mesh refinement (AMR) codes when treating massive par...
Star formation is such a complex process that accurate numerical tools are needed to quantitatively ...
Star formation is such a complex process that accurate numerical tools are needed to quantitatively ...
We implemented sink particles in the Adaptive Mesh Refinement (AMR) code FLASH to model the gravitat...
This thesis investigates the issues introduced by the advanced computing technologies applications t...
We present a detailed comparison between the well-known smoothed particle hydrodynamics (SPH) code g...
AbstractWe describe a powerful methodology for numerical solution of 3-D self-gravitational hydrodyn...