Scientific simulation, which provides a natural bridge between theory and experiment, is an essential tool for understanding complex plasma behavior. Recent advances in simulations of magnetically-confined plasmas are reviewed in this paper with illustrative examples chosen from associated research areas such as microturbulence, magnetohydrodynamics, and other topics. Progress has been stimulated in particular by the exponential growth of computer speed along with significant improvements in computer technology
The principal objective of the Computational Physics Group is to develop advanced numerical models f...
"Plasma Physics: Confinement, Transport and Collective Effects" provides an overview of modern plasm...
The research into magnetic confinement of plasmas has been primarily driven by fusion reactor develo...
Numerical calculations have had an important role in fusion research since its beginning, but the ap...
Computers have made dramatic progress in the second half of the 20th century and in the 21st century...
Plasma modelling is an exciting subject in which virtually all physical disciplines are represented....
This paper offers practical suggestions for how to make the best use of com-puters to model plasma b...
This thesis is in the form of a background research. It contains pictures, schemes and colored graph...
The physics of magnetically confined plasmas has had much of its development as part of the pro-gram...
Our research group uses both theory and simulation as tools in order to increase the understanding o...
In June of 2003, about 250 computational scientists and mathematicians being funded by the DOE Offic...
International audienceThe mathematical modeling and computer simulation of low-temperature plasmas i...
The present lecture provides an introduction to the subject of gyrokinetic theory with applications ...
This paper highlights the scientific and computational challenges facing the Fusion Simulation Progr...
Progress in three research areas has been achieved. (1) A new expression for the trapping probabilit...
The principal objective of the Computational Physics Group is to develop advanced numerical models f...
"Plasma Physics: Confinement, Transport and Collective Effects" provides an overview of modern plasm...
The research into magnetic confinement of plasmas has been primarily driven by fusion reactor develo...
Numerical calculations have had an important role in fusion research since its beginning, but the ap...
Computers have made dramatic progress in the second half of the 20th century and in the 21st century...
Plasma modelling is an exciting subject in which virtually all physical disciplines are represented....
This paper offers practical suggestions for how to make the best use of com-puters to model plasma b...
This thesis is in the form of a background research. It contains pictures, schemes and colored graph...
The physics of magnetically confined plasmas has had much of its development as part of the pro-gram...
Our research group uses both theory and simulation as tools in order to increase the understanding o...
In June of 2003, about 250 computational scientists and mathematicians being funded by the DOE Offic...
International audienceThe mathematical modeling and computer simulation of low-temperature plasmas i...
The present lecture provides an introduction to the subject of gyrokinetic theory with applications ...
This paper highlights the scientific and computational challenges facing the Fusion Simulation Progr...
Progress in three research areas has been achieved. (1) A new expression for the trapping probabilit...
The principal objective of the Computational Physics Group is to develop advanced numerical models f...
"Plasma Physics: Confinement, Transport and Collective Effects" provides an overview of modern plasm...
The research into magnetic confinement of plasmas has been primarily driven by fusion reactor develo...