Stéphane Heuraux scite author profile

Équipe 107 : Physique des plasmas chaudsInternational audienceDuring the 2011 experimental campaign, one of the three ion cyclotron resonance heating (ICRH) antennas in the Tore Supra tokamak was equipped with a new type of Faraday screen (FS). The new design aimed at minimizing the integrated parallel electric field over long field lines as well as increasing the heat exhaust capability of the actively cooled screen. It proved to be inefficient for attenuating the radio-frequency (RF)-sheaths on the screen itself on the contrary to the heat exhaust concept that allowed operation despite higher heat fluxes on the antenna. In parallel, a new approach has been proposed to model self-consistently RF sheaths: the SSWICH (Self-consistent Sheaths and Waves for IC Heating) code. Simulations results from SSWICH coupled with the TOPICA antenna code were able to reproduce the difference between the two FS designs and part of the spatial pattern of heat loads and Langmuir probe floating potential. The poloidal pattern is a reliable result that mainly depends on the electrical design of the antenna while the radial pattern is on the contrary highly sensitive to loosely constrained parameters such as perpendicular conductivity that generates a DC current circulation from the private region inside the antenna limiters to the free scrape off layer outside these limiters. Moreover, the cantilevered bars seem to be the element in the screen design that enhanced the plasma potential

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Self consistent radio-frequency wave propagation and peripheral direct current plasma biasing: Simplified three dimensional non-linear treatment in the “wide sheath” asymptotic regime

Colas¹,

Jacquot²,

Heuraux³

et al. 2012

Physics of Plasmas

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Edge plasma density convection during ion cyclotron resonance heating on Tore Supra

Becoulet¹,

Colas²,

Pécoul³

et al. 2002

Physics of Plasmas

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Turbulence in the TORE SUPRA Tokamak: Measurements and Validation of Nonlinear Simulations

Casati¹,

Gerbaud

Hennequin

et al. 2009

Phys. Rev. Lett.

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Turbulence measurements in TORE SUPRA tokamak plasmas have been quantitatively compared to predictions by nonlinear gyrokinetic simulations. For the first time, numerical results simultaneously match within experimental uncertainty (a) the magnitude of effective heat diffusivity, (b) rms values of density fluctuations, and (c) wave-number spectra in both the directions perpendicular to the magnetic field. Moreover, the nonlinear simulations help to revise as an instrumental effect the apparent experimental evidence of strong turbulence anisotropy at spatial scales of the order of ion-sound Larmor radius.

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Status and prospects for mm-wave reflectometry in ITER

Vayakis¹,

Walker

Clairet

et al. 2006

Nucl. Fusion

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Recent results on turbulence and MHD activity achieved by reflectometry

Sabot

Clairet

Conway

et al. 2006

Plasma Phys. Control. Fusion

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RF current distribution and topology of RF sheath potentials in front of ICRF antennae

et al. 2005

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Measurement of sheath potential in RF-biased flux tubes using a retarding field analyzer in Tore Supra tokamak

Kubic¹,

Gunn²,

Heuraux

et al. 2013

Journal of Nuclear Materials

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