A. Cravotta scite author profile

Magnetic field lines and the corresponding particle orbits are computed for a typical chaotic magnetic field provided by a magnetohydrodynamics numerical simulation of the reversed-field pinch. The m = 1 modes are phase locked and produce a toroidally localized bulging of the plasma which increases particle transport. The m = 0 and m = 1 modes produce magnetic chaos implying poor confinement. However, they also allow for the formation of magnetic islands which induce transport barriers inside the reversal surface.

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Active MHD control at high currents in RFX-mod

Martini¹,

Agostini²,

Alessi³

et al. 2007

Nucl. Fusion

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The modified RFX is a very flexible device used for a variety of control schemes for MHD instabilities and for advanced reverse field pinch scenarios. Relative to the previous machine, RFX-mod has a thin Cu shell with vertical field penetration time τS, lowered from 450 to 50 ms and shell/plasma proximity from b/a = 1.24–1.1. Toroidal equilibrium is feedback-controlled and new power supplies provide better Bϕ control. Newly designed graphite tiles protect the vessel from localized power deposition. A mesh of 192 external saddle coils, supervised by a digital feedback system, controls radial fields due to field errors and MHD modes. The paper presents an overview of the very encouraging results obtained using both new and ‘standard’ advanced operational modes in the current range 0.3–1 MA. A dramatic improvement of plasma performance was obtained by using the saddle coils to cancel all the radial field components, an operation mode dubbed virtual shell (VS). The toroidal voltage was lowered by more than 25% and the pulse length was tripled, up to 7 times the τS. Steady-state RFP pulses are now limited only by the applied volt-seconds. The improved magnetic boundary also has an effect on the tearing modes underlying the sustainment of the RFP, whose core amplitude is more than halved. The VS combined with new schemes for the active rotation of the MHD dynamo modes has allowed us to obtain reliable and well-controlled long RFP pulses in the MA current range. This results in a 100% increase in the particle and energy confinement time relative to the previous experiment and opens the possibility of exploring the machine performance in the 2 MA design range.

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Analysis and modelling of the magnetic and plasma profiles during PPCD experiments in RFX

et al. 2003

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In this paper, we analyse the main features of the pulsed poloidal current drive (PPCD) technique, used in the reversed field pinch configuration to achieve improved confinement conditions. In the RFX experiment, PPCD corresponds to a decrease of the magnetic fluctuations, to a peaking of the temperature profile, and to a reduced transport and plasmawall interaction. A three-dimensional MHD nonlinear code and one-dimensional time-dependent transport models have been applied to study the effect of PPCD on the magnetic and plasma profiles. The three-dimensional MHD simulations show that the external inductive drive pinches and peaks the current profile driving the configuration through a transient phase, where the spontaneous turbulent dynamo action is quenched. The one-dimensional transport codes indicate that the experimental profile modifications associated with PPCD are consistent with a reduction of the stochastic transport.

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A statistical analysis of pulsed poloidal current drive in the Reversed Field eXperiment

Cravotta

Spizzo

Terranova

et al. 2003

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Pulsed poloidal current drive (PPCD) experiments have been performed in the reversed-field pinch device RFX [G. Rostagni, Fus. Eng. Design 25, 301 (1995)], with various control techniques of the edge toroidal field. A detailed statistical analysis has been performed over ~430 RFX pulses and is presented in this paper. We have found that the temperature increase and m=1 fluctuations reduction scale with the applied electric field Eθ, which is a control parameter for plasma performances. Soft x-ray imaging shows an increase in the core, where often an m=1 helical coherent structure appears, similar to those observed during quasi-single helicity states in RFX. These phenomena are ultimately linked to the magnetic turbulence reduction and q profile modifications that take place during PPCD in the reversed-field pinch

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A. Cravotta

Overview of quasi-single helicity experiments in reversed field pinches

Transport Barrier inside the Reversal Surface in the Chaotic Regime of the Reversed-Field Pinch

Active MHD control at high currents in RFX-mod

Analysis and modelling of the magnetic and plasma profiles during PPCD experiments in RFX

A statistical analysis of pulsed poloidal current drive in the Reversed Field eXperiment

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