Abstract
A cross-regime (L-mode, I-mode and H-mode) database combining scrape-off layer (SOL) power decay length λq divertor measurements and upstream SOL electron pressure, temperature and density decay lengths has been assembled at ASDEX Upgrade. It is found that a cross-regime λq scaling is best described by a local edge quantity, such as the edge electron pressure evaluated at ρpol = 0.95. Furthermore, λq exhibits a clear correlation with edge electron pressure gradient lengths, no matter if taken inside or outside the separatrix. In addition, the database reveals that SOL and pedestal electron pressure gradients are remarkably well correlated across all confinement regimes. The physical interpretation of this observation is discussed with regard to an edge pressure critical gradient paradigm governing the edge physics and to a turbulence spreading in the SOL. Moreover, it is shown that the Spitzer–Härm electron conduction regime is a reasonable approximation to estimate λq across different confinement regimes. The main implication of these findings is that a widening of λq is linked to a reduction of edge electron pressure gradients.
Highlights
A cross-regime (L-mode, I-mode and H-mode) database combining scrape-off layer (SOL) power decay length λq divertor measurements and upstream SOL electron pressure, temperature and density decay lengths has been assembled at ASDEX Upgrade
A database that combines divertor λq measurements and SOL electron pressure, temperature and density decay lengths at the same time has been assembled at ASDEX Upgrade
The database encompasses different confinement regimes (L-mode, I-mode, inter-Edge Localized Modes (ELMs) H-mode and stationary ELM-free H-mode), different divertor geometries and different ion ∇ B drift directions. This database allows us to study λq correlations that may hold for very different confinement regimes and divertor conditions
Summary
Power exhaust is one of the key challenges on the way to commercial fusion power plants. The power crossing the separatrix enters a region called the scrape-off layer (SOL), which is characterized by magnetic field lines intercepting the first wall. The related heat flux, if not lost by volumetric processes in the SOL, reaches the divertor target plates and must not exceed material limits [1]. One of the key quantities that sets the peak heat flux entering the divertor chamber is the so-called exponential power decay
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