The results of an extensive study on transport mechanisms and on improved confinement scenarios in RFX are reported. The scaling of the thermal conductivity in the core with the Lundquist number indicates that the magnetic field in this region is not fully stochastic, as proved by the existence of thermal barriers observed in Single Helicity configurations. The electrostatic transport at the edge has been proved to depend on the highly sheared ExB flow which has been interpreted by fluid and Monte Carlo models. Regimes of improved confinement have been obtained in the core by Poloidal Current Drive techniques and the electrostatic transport has been reduced at the edge by biasing experiments. A radiation mantle by impurity seeding has been found to successfully reduce the local plasma wall interaction without significantly deteriorating the plasma performance.

Transport Mechanisms and Enhanced Confinement Studies in RFX

V Antoni;M Valisa;S Cappello;L Carraro;A De Lorenzi;E Gaio;P Innocente;A Luchetta;G Manduchi;G Marchiori;L Marrelli;E Martines;S Martini;A Murari;R Paccagnella;R Pasqualotto;S Peruzzo;R Piovan;N Pomaro;ME Puiatti;P Scarin;G Serianni;G Spizzo;M Spolaore;C Taliercio;D Terranova;V Toigo;N Vianello;P Zaccaria;
2001

Abstract

The results of an extensive study on transport mechanisms and on improved confinement scenarios in RFX are reported. The scaling of the thermal conductivity in the core with the Lundquist number indicates that the magnetic field in this region is not fully stochastic, as proved by the existence of thermal barriers observed in Single Helicity configurations. The electrostatic transport at the edge has been proved to depend on the highly sheared ExB flow which has been interpreted by fluid and Monte Carlo models. Regimes of improved confinement have been obtained in the core by Poloidal Current Drive techniques and the electrostatic transport has been reduced at the edge by biasing experiments. A radiation mantle by impurity seeding has been found to successfully reduce the local plasma wall interaction without significantly deteriorating the plasma performance.
2001
Istituto gas ionizzati - IGI - Sede Padova
REVERSED-FIELD-PINCH
ELECTROSTATIC TURBULENCE
PLASMA
REDUCTION
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.14243/25394
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