This paper explains how to obtain the distribution function of minority ions in tokamak plasmas using the Monte Carlo method. Since the emphasis is on energetic ions, the guiding-center transformation is outlined, including also the transformation of the collision operator. Even within the guiding-center formalism, the fast particle simulations can still be very CPU intensive and, therefore, we introduce the reader also to the world of high-performance computing. The paper is concluded with a few examples where the presented method has been applied
We report an accessible and robust tool for evaluating the effects of Coulomb collisions on a test p...
Abstract: The general DSMC method for solving Boltzmann equation for long-range potentials...
In plasma physics, the direct simulation of inter-particle Coulomb collisions is often necessary to ...
This paper explains how to obtain the distribution function of minority ions in tokamak plasmas usin...
A comprehensive description of methods, suitable for solving the kinetic equation for fast ions and ...
A comprehensive description of methods, suitable for solving the kinetic equation for fast ions and ...
The following topics were dealt with: A kinetic equation for the transport of charged test particles...
Understanding and simulating the dynamics of plasmas in Tokamak devices is a crucial aspect of the p...
AbstractA procedure for performing Monte Carlo calculations of plasmas with an arbitrary level of de...
For tokamaks the Monte Carlo technique is a powerful method to study kinetic phenom-ena in plasmas...
One of the main challenges for the realization of a working fusion power plant is an increased detai...
A new calculation of atomic kinetics of multiple-charged tungsten ions in a high temperature plasma ...
In the study of charged particle transport in plasmas, numerical techniques for solving the Fokker-P...
We present a new, for plasma physics, highly efficient multilevel Monte Carlo numer-ical method for ...
This presentation describes a hybrid computational method for Coulomb collisions in a plasma that co...
We report an accessible and robust tool for evaluating the effects of Coulomb collisions on a test p...
Abstract: The general DSMC method for solving Boltzmann equation for long-range potentials...
In plasma physics, the direct simulation of inter-particle Coulomb collisions is often necessary to ...
This paper explains how to obtain the distribution function of minority ions in tokamak plasmas usin...
A comprehensive description of methods, suitable for solving the kinetic equation for fast ions and ...
A comprehensive description of methods, suitable for solving the kinetic equation for fast ions and ...
The following topics were dealt with: A kinetic equation for the transport of charged test particles...
Understanding and simulating the dynamics of plasmas in Tokamak devices is a crucial aspect of the p...
AbstractA procedure for performing Monte Carlo calculations of plasmas with an arbitrary level of de...
For tokamaks the Monte Carlo technique is a powerful method to study kinetic phenom-ena in plasmas...
One of the main challenges for the realization of a working fusion power plant is an increased detai...
A new calculation of atomic kinetics of multiple-charged tungsten ions in a high temperature plasma ...
In the study of charged particle transport in plasmas, numerical techniques for solving the Fokker-P...
We present a new, for plasma physics, highly efficient multilevel Monte Carlo numer-ical method for ...
This presentation describes a hybrid computational method for Coulomb collisions in a plasma that co...
We report an accessible and robust tool for evaluating the effects of Coulomb collisions on a test p...
Abstract: The general DSMC method for solving Boltzmann equation for long-range potentials...
In plasma physics, the direct simulation of inter-particle Coulomb collisions is often necessary to ...