Your search keyword '"V Vershkov"' showing total 2 results

1. Turbulence studies with means of reflectometry at TEXTOR

Author

A Krämer-Flecken, V Dreval, S Soldatov, A Rogister, V Vershkov, and the TEXTOR-team

Subjects

Physics, Nuclear and High Energy Physics, business.industry, Turbulence, Magnetic confinement fusion, Condensed Matter Physics, Neutral beam injection, Computational physics, Optics, Amplitude, Physics::Plasma Physics, Physics::Space Physics, Wavenumber, ddc:530, Plasma diagnostics, Phase velocity, business, Reflectometry

Abstract

At TEXTOR, an O-mode heterodyne reflectometer system is installed and operated for the measurement of plasma density fluctuations and turbulence investigations. With two antenna arrays in the equatorial and top positions having two and three horn antennae, respectively, poloidal correlations are investigated under different plasma scenarios. From the amplitude, cross-phase and coherency spectrum, differences in the ohmic and auxiliary heated discharges are investigated. Furthermore the dynamic behaviour of the turbulence is studied in the SOC-IOC transition and in the precursor phase of a disruption. For the latter an increased integrated power spectral density was observed at the X-point of the mode compared with the O-point. Stationary m = 2 mode activity is observed for the first time at TEXTOR by reflectometry. The fluctuation level is calculated for different conditions and rises significantly increasing heating power which is consistent with the L-mode confinement degradation. Correlation measurements yield the measured phase delays which are used to calculate the poloidal phase velocity perpendicular to the magnetic field. In ohmic plasmas the turbulence rotates like a 'rigid body' with constant angular velocity inside the q = 2 surface. The rigid body rotation is broken up during tangential neutral beam injection. From the deduced poloidal wavenumber of the turbulence, most likely ion temperature gradient modes are the driving mechanism of the turbulence.

Published

2004

2. Steady improved confinement in FTU high field plasmas sustained by deep pellet injection

Author

B. Angelini, C. Castaldo, E. Giovannozzi, D. Frigione, C. Gormezano, H. Kroegler, V. Vershkov, L. Garzotti, Paolo E. Trevisanutto, R. Cesario, Francesca Poli, F. Crisanti, Giovanni Bracco, O. Tudisco, Fulvio Zonca, V. Cocilovo, A. Bertocchi, P. Chuilon, G. Apruzzese, Francesco Mirizzi, M. Leigheb, L. Pieroni, F. De Marco, L. Panaccione, P. Smeulders, A.A. Petrov, M. De Benedetti, B. Esposito, L. Gabellieri, S. E. Segre, G. Pulcella, M. Marinucci, Francesco Romanelli, E. Barbato, M.L. Apicella, S. Cascino, A. A. Tuccillo, Luciano Bertalot, G. Maffia, M. Zerbini, F. Alladio, G. Maddaluno, P. Buratti, F. Iannone, G.B. Righetti, F. Santini, E. Stermini, Gregorio Vlad, M. Romanelli, G. Buceti, M. Grolli, Cristina Centioli, G. Mazzitelli, M. Sassi, Giancarlo Gatti, P. Micozzi, A. Cardinali, F. Gravanti, G. L. Ravera, N. Tartoni, R. De Angelis, B. Tilia, M. Panella, V. Zanza, V. Vitale, V. Pericoli-Ridolfini, D. Pacella, Salvatore Podda, and P. Papitto

Subjects

Coupling, Nuclear and High Energy Physics, Materials science, Toroidal field, Plasma, Alpha particle, Condensed Matter Physics, Settore FIS/07 - Fisica Applicata(Beni Culturali, Ambientali, Biol.e Medicin), Core (optical fiber), Physics::Plasma Physics, Pellet, Neutron, High field, Atomic physics

Abstract

High density plasmas (n0 ≈ 8 × 1020m-3) featuring steady improved core confinement have been obtained in FTU up to the maximum nominal toroidal field (8 T) by deep multiple pellet injection. These plasmas also feature high purity efficient electron-ion coupling and peaked density profiles sustained for several confinement times. Neutron yields in excess of 1 × 1013 n/s are measured, consistent with the reduction of the ion transport to neoclassical levels.

Published

2001