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Density limit studies in the tokamak and the reversed-field pinch
- Source :
- Nuclear Fusion, Nuclear fusion 55 (2015). doi:10.1088/0029-5515/55/4/043007, info:cnr-pdr/source/autori:Spizzo G.; Pucella G.; Tudisco O.; Zuin M.; Agostini M.; Alessi E.; Auriemma F.; Bin W.; Buratti P.; Carraro L.; Cavazzana R.; Ciaccio G.; De Masi G.; Esposito B.; Galperti C.; Garavaglia S.; Granucci G.; Marinucci M.; Marrelli L.; Martines E.; Mazzotta C.; Minelli D.; Moro A.; Puiatti M. E.; Scarin P.; Sozzi C.; Spolaore M.; Schmitz O.; Vianello N.; White R. B./titolo:Density limit studies in the tokamak and the reversed-field pinch/doi:10.1088%2F0029-5515%2F55%2F4%2F043007/rivista:Nuclear fusion/anno:2015/pagina_da:/pagina_a:/intervallo_pagine:/volume:55
- Publication Year :
- 2015
-
Abstract
- The ITER scenarios and the project of DEMO involve stable operation above the Greenwald density, which justifies efforts to understand and overcome the density limit, this last observed as a disruptive termination of tokamak discharges and a thermal crash (with no disruption) of stellarator and reversed-field pinch (RFP) ones. Both in the tokamak and the RFP, new findings show that the high density limit is not governed by a unique, theoretically well-determined physical phenomenon, but by a combination of complex mechanisms involving two-fluid effects, electrostatic plasma response to magnetic islands and plasma-wall interaction. In this paper we will show new evidence challenging the traditional picture of the 'Greenwald limit', in particular with reference to the role of thermal instabilities and the edge radial electric field Er in the development of this limit. © 2015 EURATOM.
- Subjects :
- Nuclear and High Energy Physics
RADIAL ELECTRIC-FIELD
Tokamak
particle orbits
design
CONFINEMENT
plasmamaterial interactions
law.invention
plasmamaterial interaction
PARTICLE-TRANSPORT
law
Electric field
Thermal
and computerized simulation
Limit (mathematics)
theory
MARFE
particle orbit and trajectory
Physics
boundary layer effects
two-fluid and multi-fluid plasmas
Condensed Matter Physics
DISCHARGES
RFX-MOD
PLASMA
Reversed field pinch
Mechanics
Plasma
particle orbit
ASDEX UPGRADE
plasma-material interactions
boundary layer effect
two-fluid and multi-fluid plasma
Pinch
TURBULENCE
Atomic physics
Stellarator
Subjects
Details
- ISSN :
- 00295515, 07413335, 15361055, and 00030503
- Database :
- OpenAIRE
- Journal :
- Nuclear Fusion
- Accession number :
- edsair.doi.dedup.....f31cf4bbfab358c72a6d69d2d9cdf60a
- Full Text :
- https://doi.org/10.1088/0029-5515/55/4/043007