Global fluid simulation of plasma turbulence in a stellarator with an island divertor

Coelho, António J; Loizu, Joaquim; Ricci, Paolo; Giacomin, Maurizio

doi:10.1088/1741-4326/ac6ad2

Cited by 9 publications

(36 citation statements)

References 36 publications

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“…The equilibrium density profile agrees well with the experiment, but in the case of the electron temperature the value on axis is underestimated. As experimentally observed in TJ-K and confirmed by the GBS simulations presented here, the turbulent transport is mainly due to a low-m mode, something that was also recently observed in an GBS simulation of a stellarator with an island divertor [8]. This contrasts with the typical plasma turbulence in tokamaks, where more broadband turbulence is observed.…”

Section: Discussionsupporting

confidence: 85%

“…an extension of the BOUT++ code [3], simulated seeded filaments in a rotating ellipse [4]. More recently, the first global flux-driven simulations of a stellarator, performed by using the GBS code [5][6][7], considered a vacuum magnetic field generated with the Dommaschk potentials, reporting important differences with respect to tokamak simulations, namely the existence of a low-m mode, where m is the poloidal mode number, dominating the turbulent transport [8]. Such surprising result calls for the validation of turbulence simulations in stellarators.…”

Section: Introductionmentioning

confidence: 99%

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Validation of GBS plasma turbulence simulation of the TJ-K stellarator

Coelho

Loizu

Ricci

et al. 2023

Plasma Phys. Control. Fusion

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We present a validation of a three-dimensional, two-fluid simulation of plasma turbulence in the TJ-K stellarator, a low temperature plasma experiment ideally suited for turbulence measurements. The simulation is carried out by the GBS code, recently adapted to simulate 3D magnetic fields. The comparison shows that GBS retrieves the main turbulence properties observed in the device, namely the fact that transport is dominated by fluctuations with low poloidal mode number. The poloidal dependence of the radial $\text{E}\times\text{B}$ turbulent flux is compared on a poloidal plane with elliptical flux surfaces, where a very good agreement between experiment and simulation is observed, and on another with triangular flux surfaces, which shows a poorer comparison. The fluctuation levels in both cases are underestimated in the simulations. The equilibrium density profile is well retrieved by the simulation, while the electron temperature and the electrostatic potential profiles, which are very sensitive to the strength and localization of the sources, do not agree well with the experimental measurements.

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Section: Discussionsupporting

confidence: 85%

Section: Introductionmentioning

confidence: 99%

Validation of GBS plasma turbulence simulation of the TJ-K stellarator

Coelho

Loizu

Ricci

et al. 2023

Plasma Phys. Control. Fusion

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“…Initially developed to study turbulence in basic plasma physics experiments [37] and limited tokamak configurations, the GBS code [38][39][40] solves the drift-reduced Braginskii equations to evolve plasma turbulence at the tokamak boundary. The implementation of a spatial discretization algorithm independent of the magnetic field [41] allows GBS to simulate diverted configurations with an arbitrary magnetic equilibrium [42,43], as well as non-axisymmetric configurations, such as the stellarators [44]. While the plasma model implemented in GBS was developed in recent years to include the neutral dynamics [45], we do not include it in the simulations presented here, therefore focusing on the sheath-limited regime, where only pure plasma composed of ions and electrons, without radiative impurities, is considered in the present study.…”

Section: Numerical Modelmentioning

confidence: 99%

Effect of triangularity on plasma turbulence and the SOL-width scaling in L-mode diverted tokamak configurations

Lim

Giacomin

Ricci

et al. 2023

Plasma Phys. Control. Fusion

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The effect of triangularity on tokamak boundary plasma turbulence is investigated by using global, flux-driven, three-dimensional, two-fluid simulations. The simulations show that negative triangularity stabilizes boundary plasma turbulence, and linear investigations reveal that this is due to a reduction of the magnetic curvature drive of interchange instabilities, such as the resistive ballooning mode. As a consequence, the pressure decay length $L_p$, related to the SOL power fall-off length $\lambda_q$, is found to be affected by triangularity. Leveraging considerations on the effect of triangularity on the linear growth rate and nonlinear evolution of the resistive ballooning mode, the analytical theory-based scaling law for $L_p$ in L-mode plasmas, derived by Giacomin \textit{et al.} [{Nucl. Fusion}, \href{https://doi.org/10.1088/1741-4326/abf8f6}{\textbf{61} 076002} (2021)], is extended to include the effect of triangularity. The scaling is in agreement with nonlinear simulations and a multi-machine experimental database, which include recent TCV discharges dedicated to the study of the effect of triangularity in L-mode diverted discharges. Overall, the present results highlight that negative triangularity narrows the $L_p$ and considering the effect of triangularity is important for a reliable extrapolation of $\lambda_q$ from present experiments to larger devices.

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“…Two-dimensional codes applicable to the tokamak SOL such as UEDGE [16] and SOLPS [17] include drifts, but they are not always turned on in simulations due to computational cost, especially when drift effects are not the primary focus of investigation. Drift modeling in stellarators is in its infancy: there are currently no 3D SOL codes with plasmaneutral coupling that self-consistently include drifts, although recently a two-fluid edge turbulence code that includes drifts but not neutrals has been developed [18]. Efforts are underway to add drifts to EMC3-Eirene [19], the primary SOL code used to model W7-X, but a functional implementation is not complete.…”

Section: Introductionmentioning

confidence: 99%

Effects of drifts on scrape-off layer transport in W7-X

et al. 2023

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Drifts affect particle, momentum, and energy transport in the scrape-off layer (SOL) of tokamaks and stellarators, altering plasma flows and creating asymmetries between divertors. To understand how drifts affect SOL transport in the W7-X island divertor, an experiment was performed to compare plasmas with matched core parameters but opposite magnetic field directions, and therefore opposite drift transport directions. Parallel flow measurements made with coherence imaging spectroscopy are interpreted with the aid of a diagnostic forward model and a 1D simple SOL model that includes the E × B drift. In low-density plasmas (n e < 2 × 1019 m−3), the poloidal E × B drift induces a large poloidal density asymmetry within the island SOL, as measured by divertor Langmuir probes. This in turn causes the parallel flow stagnation point to shift from the position halfway between targets to the X-point in the drift direction, leading to near-unidirectional flow throughout the SOL. As density increases, the effects of the poloidal E × B drift decrease substantially, resulting in a smaller density asymmetry and the development of a counter-streaming flow pattern. For the entire density range probed in this experiment (n e = 1.5–6 × 1019 m−3), the experimental observations are more consistent with the effects of the poloidal E × B drift than the radial E × B drift.

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Global fluid simulation of plasma turbulence in a stellarator with an island divertor

Cited by 9 publications

References 36 publications

Validation of GBS plasma turbulence simulation of the TJ-K stellarator

Validation of GBS plasma turbulence simulation of the TJ-K stellarator

Effect of triangularity on plasma turbulence and the SOL-width scaling in L-mode diverted tokamak configurations

Effects of drifts on scrape-off layer transport in W7-X

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