Edge ambipolar potential in toroidal fusion plasmas

Spizzo, G.; Vianello, N.; White, R. B.; Abdullaev, S. S.; Agostini, M.; Cavazzana, R.; Ciaccio, G.; Puiatti, M. E.; Scarin, P.; Schmitz, O.; Spolaore, M.; Terranova, D.

doi:10.1063/1.4872173

Cited by 17 publications

(27 citation statements)

References 55 publications

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“…This potential is the response of the plasma to non-ambipolar fluxes, generated through the breaking of the toroidal symmetry by the 3D fields. Similar results have been obtained in the RFX-mod RFP, where a model of electrostatic potential was built up for the island resonating with poloidal/toroidal mode number m/n = 0/1 at the edge of RFX-mod [47]. This model reproduces the main features of E r , such as amplitude and geometry along the toroidal angle ϕ.…”

Section: Methodssupporting

confidence: 59%

“…Our results have been obtained in the case of a static RMP: this solution is valid even in the case of slowly rotating islands, as in the case of RFX [47]. In the case of fast rotating islands (in TEXTOR, with frequency ω > 3 kHz), it is necessary to account for an inductive correction for Φ, due to the term ∂ t α B that adds to the expression of Eq.…”

Section: Maps Of Plasma Potential: Experiments and Simulationsmentioning

confidence: 99%

“…In particular, the correlation is very strong in the region outside the LCFS, while inside V p does not follow exactly the flux surfaces. On the basis of the simulations of D and the measured V p map, we find good reason to assume that the ambipolar potential Φ should possess the same geometry as the 4/1 island, similarly to the 0/1 and 1/7 island cases in RFX-mod [17,47].…”

Section: Maps Of Plasma Potential: Experiments and Simulationsmentioning

confidence: 99%

“…In the chaotic transport calculations with Orbit it is easier to find a proper analytic form for Φ to stick into the GC equations of motion, Eqs (1,2). To do that, we need to mix an experimental radial profile and simulation observations along θ, as previously done on RFX-mod [47]. In this way,…”

Section: Maps Of Plasma Potential: Experiments and Simulationsmentioning

confidence: 99%

“…In Ref. [47] we presented the calculation of the particle diffusion coefficients, D, in between fixed points, O and X (OP and XP in the remainder of the paper). Here, we propose again the result as it is instrumental to the measurements of plasma potential and the modeled ambipolar potential, that we present below.…”

Section: Maps Of Plasma Potential: Experiments and Simulationsmentioning

confidence: 99%

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Helical modulation of the electrostatic plasma potential due to edge magnetic islands induced by resonant magnetic perturbation fields at TEXTOR

et al. 2015

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The electrostatic response of the edge plasma to a magnetic island induced by resonant magnetic perturbations to the plasma edge of the circular limiter tokamak TEXTOR is analyzed. Measurements of plasma potential are interpreted with simulations with the Hamiltonian guiding center code Orbit. We find a strong correlation between the magnetic field topology and the poloidal modulation of the measured plasma potential. The ion and electron drifts yield a predominantly electron driven radial diffusion when approaching the island X-point while ion diffusivities are generally an order of magnitude smaller. This causes a strong radial electric field structure pointing outward from the island O-point. The good agreement found between measured and modeled plasma potential connected to the enhanced radial particle diffusivities supports that a magnetic island in the edge of a tokamak plasma can act as convective cell. We show in detail that the particular, non-ambipolar drifts of electrons and ions in a 3D magnetic topology account for theseeffects. An analytical model for the plasma potential is implemented in the code Orbit, and analyses of ion and electron radial diffusion show that both ion-and electron-dominated transport regimes can exist, which are known as ion and electron root solutions in stellarators. This finding and comparison with reversed field pinch studies and stellarator literature suggests that the role of magnetic islands as convective cells and hence as major radial particle transport drivers could be a generic mechanism in 3D plasma boundary layers.

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Section: Methodssupporting

confidence: 59%

Section: Maps Of Plasma Potential: Experiments and Simulationsmentioning

confidence: 99%

Section: Maps Of Plasma Potential: Experiments and Simulationsmentioning

confidence: 99%

Section: Maps Of Plasma Potential: Experiments and Simulationsmentioning

confidence: 99%

Section: Maps Of Plasma Potential: Experiments and Simulationsmentioning

confidence: 99%

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Helical modulation of the electrostatic plasma potential due to edge magnetic islands induced by resonant magnetic perturbation fields at TEXTOR

et al. 2015

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Edge plasma physics modifications due to magnetic ripple in RFX-mod

Scarin¹,

Agostini²,

Carraro³

et al. 2015

Journal of Nuclear Materials

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Mechanisms of plasma disruption and runaway electron losses in the TEXTOR tokamak

et al. 2015

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Based on the analysis of data from the numerous dedicated experiments on plasma disruptions in the TEXTOR tokamak the mechanisms of the formation of runaway electron beams and their losses are proposed. The plasma disruption is caused by strong stochastic magnetic field formed due to nonlinearly excited low-mode number magnetohydro-dynamics (MHD) modes. It is hypothesized that the runaway electron beam is formed in the central plasma region confined by an intact magnetic surface due to the acceleration of electrons by the inductive toroidal electric field. In the case of plasmas with the safety factor q(0) < 1 the most stable runaway electron beams are formed by the intact magnetic surface located between the magnetic surface q = 1 and the closest loworder rational surface q = m/n > 1 ( q = 5/4, q = 4/3, . . . ). The thermal quench time caused by the fast electron transport in a stochastic magnetic field is calculated using the collisional transport model. The current quench stage is due to the particle transport in a stochastic magnetic field. The runaway electron beam current is modeled as a sum of toroidally symmetric part and a small amplitude helical current with a predominant m/n = 1/1 component. The runaway electrons are lost due to two effects: (i) by outward drift of electrons in a toroidal electric field until they touch wall and (ii) by the formation of stochastic layer of runaway electrons at the beam edge. Such a stochastic layer for high-energy runaway electrons is formed in the presence of the m/n = 1/1 MHD mode. It has a mixed topological structure with a stochastic region open to wall. The effect of external resonant magnetic perturbations on runaway electron loss is discussed. A possible cause of the sudden MHD signals accompanied by runaway electron bursts is explained by the redistribution of runaway current during the resonant interaction of high-energetic electron orbits with the m/n = 1/1 MHD mode.

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Edge ambipolar potential in toroidal fusion plasmas

Cited by 17 publications

References 55 publications

Helical modulation of the electrostatic plasma potential due to edge magnetic islands induced by resonant magnetic perturbation fields at TEXTOR

Helical modulation of the electrostatic plasma potential due to edge magnetic islands induced by resonant magnetic perturbation fields at TEXTOR

Edge plasma physics modifications due to magnetic ripple in RFX-mod

Mechanisms of plasma disruption and runaway electron losses in the TEXTOR tokamak

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