The simulations for linear devices using the 3D Monte-Carlo code ERO have a number of particularities of both physical and technical nature. Many physical effects introduced and tested for these simulations (elastic collisions, population of metastable states, etc.) can be relevant for tokamaks as well. The current status of these activities is summarized. As an example some simulations reproducing the experimental observations at PISCES-B and Pilot-PSI are presented. Main deviations and ideas for their origins are discussed. © 2010 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim
The low-impact-energy range of the data set used by the 3D Monte Carlo impurity transport code ERO h...
Abstract. The interaction of plasma with the walls has been one of the critical issues in the devel-...
Gyrokinetic simulations of ion temperature gradient mode and trapped electron mode driven impurity t...
The simulations for linear devices using the 3D Monte-Carlo code ERO have a number of particularitie...
The simulations for linear devices using the 3D Monte-Carlo code ERO have a number of particularitie...
The simulations for linear devices using the 3D Monte-Carlo code ERO have a number of particularitie...
The Monte Carlo code ERO simulates the three-dimensional transport of impurity particles in a backgr...
Die Erosion von Wandkomponenten und die Tritiumrückhaltung begrenzen die Verfügbarkeit und Lebensdau...
Thermonuclear fusion of deuterium (D) and tritium (T) has the potential to be an efficient, sustaina...
The ERO-TEXTOR code is described in detail. The code solves the kinetic equations of impurities in t...
ERO is a Monte-Carlo code for modeling plasma-wall interaction and 3D plasma impurity transport for ...
The ERO code was modified for modeling of plasma–surface interactions and impurities transport in th...
The interaction of plasma with the walls has been one of the critical issues in the development of f...
The ERO-TEXTOR code is described in detail. The code solves the kinetic equations of impurities in t...
In recent years, the rapid evolution of computing power, available computer memory and parallel proc...
The low-impact-energy range of the data set used by the 3D Monte Carlo impurity transport code ERO h...
Abstract. The interaction of plasma with the walls has been one of the critical issues in the devel-...
Gyrokinetic simulations of ion temperature gradient mode and trapped electron mode driven impurity t...
The simulations for linear devices using the 3D Monte-Carlo code ERO have a number of particularitie...
The simulations for linear devices using the 3D Monte-Carlo code ERO have a number of particularitie...
The simulations for linear devices using the 3D Monte-Carlo code ERO have a number of particularitie...
The Monte Carlo code ERO simulates the three-dimensional transport of impurity particles in a backgr...
Die Erosion von Wandkomponenten und die Tritiumrückhaltung begrenzen die Verfügbarkeit und Lebensdau...
Thermonuclear fusion of deuterium (D) and tritium (T) has the potential to be an efficient, sustaina...
The ERO-TEXTOR code is described in detail. The code solves the kinetic equations of impurities in t...
ERO is a Monte-Carlo code for modeling plasma-wall interaction and 3D plasma impurity transport for ...
The ERO code was modified for modeling of plasma–surface interactions and impurities transport in th...
The interaction of plasma with the walls has been one of the critical issues in the development of f...
The ERO-TEXTOR code is described in detail. The code solves the kinetic equations of impurities in t...
In recent years, the rapid evolution of computing power, available computer memory and parallel proc...
The low-impact-energy range of the data set used by the 3D Monte Carlo impurity transport code ERO h...
Abstract. The interaction of plasma with the walls has been one of the critical issues in the devel-...
Gyrokinetic simulations of ion temperature gradient mode and trapped electron mode driven impurity t...