Add to ORKGSystematic discrepancies between 2D fluid edge codes predictions for scrape-off layer and divertor and existing tokamak experiments are described. Possible sources of the discrepancies, including incorrect implementation of the neutral model, the role of fluctuations in the plasma and non-local kinetic effect of parallel heat transport are analysed. __________________________________________________
Our objective is to develop an accurate self-consistent model for plasma and neutral sin the edge of...
Understanding plasma profile evolution and plasma turbulence are two important aspects of developing...
The interaction between plasma and neutrals within a tokamak dominates the behaviour of the edge pla...
Edge plasma modelling is discussed with particular emphasis on the comparison of a fluid neutral mod...
Edge plasma modelling is discussed with particular emphasis on the comparison of a fluid neutral mod...
Because of the complexity of the physics in the edge of divertor tokamaks, extrapolation from presen...
The B2 two dimensional edge plasma code has found widespread application in modelling scrape-off lay...
<!-- p, li { white-space: pre-wrap; } --><p style="text-indent: 0px; margin: 0px;">In this article w...
Recently a number of major, unanticipated effects have been reported in tokamak edge research raisin...
Fluid modeling of the Tokamak edge region is a well-developod tool, employed both to understand the ...
Recent advances in the theory and modelling of tokamak edge, scrape-off-layer and divertor plasmas a...
We compare the plasma sources (particle, parallel momentum and ion energy) due to plasma-neutral int...
A novel two-dimensional (2D) fluid model is proposed for investigating flux-driven plasma turbulence...
Multi-fluid plasma edge code packages, usually coupled to Monte-Carlo transport codes for neutrals a...
Fluid models used to study the edge plasma region need to be benchmarked against similar conditions ...
Our objective is to develop an accurate self-consistent model for plasma and neutral sin the edge of...
Understanding plasma profile evolution and plasma turbulence are two important aspects of developing...
The interaction between plasma and neutrals within a tokamak dominates the behaviour of the edge pla...
Edge plasma modelling is discussed with particular emphasis on the comparison of a fluid neutral mod...
Edge plasma modelling is discussed with particular emphasis on the comparison of a fluid neutral mod...
Because of the complexity of the physics in the edge of divertor tokamaks, extrapolation from presen...
The B2 two dimensional edge plasma code has found widespread application in modelling scrape-off lay...
<!-- p, li { white-space: pre-wrap; } --><p style="text-indent: 0px; margin: 0px;">In this article w...
Recently a number of major, unanticipated effects have been reported in tokamak edge research raisin...
Fluid modeling of the Tokamak edge region is a well-developod tool, employed both to understand the ...
Recent advances in the theory and modelling of tokamak edge, scrape-off-layer and divertor plasmas a...
We compare the plasma sources (particle, parallel momentum and ion energy) due to plasma-neutral int...
A novel two-dimensional (2D) fluid model is proposed for investigating flux-driven plasma turbulence...
Multi-fluid plasma edge code packages, usually coupled to Monte-Carlo transport codes for neutrals a...
Fluid models used to study the edge plasma region need to be benchmarked against similar conditions ...
Our objective is to develop an accurate self-consistent model for plasma and neutral sin the edge of...
Understanding plasma profile evolution and plasma turbulence are two important aspects of developing...
The interaction between plasma and neutrals within a tokamak dominates the behaviour of the edge pla...