Self-consistent cross-field transport model for core and edge plasma transport

Baschetti, Serafina; Bufferand, Hugo; Ciraolo, Guido; Ghendrih, Ph.; Serre, Éric; Tamain, P.

doi:10.1088/1741-4326/ac1e60

Cited by 21 publications

(21 citation statements)

References 117 publications

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“…We have thus obtained a set of mean-field Equations ( 17)-( 20) and ( 28) which can be solved for the mean-field quantities n, ũ|| , Ti , Te and 𝜙. Not surprisingly, the structure of these equations is very similar to that of the original fluid turbulence Equations ( 1)-( 4) and (16). In general, the same terms are present in the mean-field equations, but evaluated with the mean-field (i.e., averaged) values of the parameters.…”

Section: Mean-field Equationsmentioning

confidence: 90%

“…so that the closures proposed in Equations ( 30), ( 32) and ( 33) can be used to close the interchange term. This exact relation between the interchange source and the turbulent ion and electron heat fluxes is a key feature of the model, and is to be seen in contrast to the work of References [15,16,19], where a model for the interchange source is proposed based on the linear growth rate of the interchange instability. Note in particular that the term in itself is always present in the equation of 𝜅, and while we call it 'interchange source', its form is not specific to interchange turbulence.…”

Section: Interchange Source Of 𝜿mentioning

confidence: 97%

“…To obtain the corresponding set of mean-field equations, we split each quantity above in mean and fluctuating components, and time-average the governing Equations ( 1)-( 4) and (16). For a general quantity x we have either a Reynolds decomposition x = x + x ′ , or a Favre decomposition x = x + x ′′ , where x = lim T→∞ 1 T ∫ T xdt and x = nx∕n .…”

Section: Mean-field Equationsmentioning

confidence: 99%

“…Moreover, knowledge and insights obtained with these codes is not fully integrated in the edge codes at present. This paper focuses on further development of simplified yet self-consistent transport models based on the so-called Reynolds-Averaged Navier Stokes (RANS) approach from hydrodynamic turbulence, [14] recently introduced for plasma edge modelling in References [15][16][17]. These models do not resolve the turbulent length and time scales, and can be solved at a strongly reduced computational cost comparable to that of regular transport simulations, while providing a significant step forward compared to ad-hoc transport descriptions.…”

Section: Introductionmentioning

confidence: 99%

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A self‐consistent κ‐model for anomalous transport due to electrostatic, interchange‐dominated E × B drift turbulence in the scrape‐off layer and implementation in SOLPS‐ITER

Dekeyser

Coosemans

Carli

et al. 2022

Contributions to Plasma Physics

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The ad‐hoc description of anomalous transport through diffusive relations with manually tuned coefficients is currently one of the main limitations in mean‐field plasma edge codes, seriously restricting their interpretive and predictive capabilities. In this paper, we attempt to improve that description by relating the anomalous transport coefficients to the turbulent kinetic energy κ as a measure for the local intensity of the turbulence. Using RANS techniques from hydrodynamic turbulence and insights from their recent successful application to 2D electrostatic E×B drift turbulence modelling for the scrape‐off layer, we propose a transport equation for κ and discuss its coupling with the mean‐field transport equations. The main features of the model include (a) an analytically exact interchange source of κ which introduces the ballooning character of the transport; (b) fast parallel transport of κ through the connection with parallel current fluctuations; and (c) consistent transport reduction due to the impact of mean E×B flow shear. The resulting model has been implemented in the new extended grids version of SOLPS‐ITER, enabling for the first time mean‐field simulations self‐consistently combining classical parallel transport with mean‐field drifts and anomalous transport with the code. A first assessment of the model has been made for a representative C‐Mod case study, highlighting the promising features of the model. Further analysis is needed to investigate in detail the impact of the different new terms in the model across operational regimes, and determine the new closures constants based on larger sets of turbulence simulations and experimental data.

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Section: Mean-field Equationsmentioning

confidence: 90%

Section: Interchange Source Of 𝜿mentioning

confidence: 97%

Section: Mean-field Equationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

A self‐consistent κ‐model for anomalous transport due to electrostatic, interchange‐dominated E × B drift turbulence in the scrape‐off layer and implementation in SOLPS‐ITER

Dekeyser

Coosemans

Carli

et al. 2022

Contributions to Plasma Physics

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show abstract

“…This reduces the computational cost, which in turn allows transport models to be run for large machines and over long time-scales. However, one limitation of transport modelling is that the diffusive transport coefficients are not self-consistently determined, and instead must be either heuristically fitted to experimental data, computed via reduced models [8] or determined via a coupled turbulence code [9], [10]. This can provide a reasonable match to the mean plasma profiles of existing devices, but cannot describe the timedependent behaviour of the plasma.…”

Section: Introductionmentioning

confidence: 99%

Validation of edge turbulence codes against the TCV-X21 diverted L-mode reference case

Oliveira,

Body,

Galassi

et al. 2021

Preprint

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Full-size turbulence simulations of the divertor and scrape-off-layer of existing tokamaks have recently become feasible, allowing direct comparisons of turbulence simulations to experimental measurements. We present a validation of three flux-driven turbulence codes -GBS, GRILLIX and TOKAM3X -against an experimental dataset from diverted Ohmic L-mode discharges on the TCV tokamak. This "TCV-X21" dataset covers the divertor targets, volume, entrance and the outboard midplane via 5 diagnostic systems, giving a total of 45 comparison observables over two toroidal field directions. The simulations show good agreement at the outboard midplane for most observables. At the divertor targets and in the divertor volume, several individual observables show good agreement, but the overall match is lower than at the outboard midplane. The simulations typically find the correct order-of-magnitude and the approximate shape for the divertor mean profiles, with the match varying for different observables and codes. The experimental profiles of the divertor density, potential, current and velocity vary strongly with field direction, while a weaker effect is found in the simulations. The simulated divertor profiles are found to be sensitive to the choice of sheath boundary conditions and the use of artificially increased collisionality. Additionally, the observed divertor flows suggest that divertor neutral ionisation is nonnegligible. This indicates that the match could be improved by using improved boundary conditions, more realistic parameters and including self-consistent neutral physics. Future validation and benchmarking against the TCV-X21 reference dataset will assess the impact of improvements to the codes and will guide their targeted development -a process which can be extended to other turbulence codes via the freely available TCV-X21 reference dataset. As such, this work assesses the current capabilities of edge/divertor turbulence simulations and provides a systematic path towards their improved interpretive and predictive capability.

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A self‐consistent mean‐field model for turbulent particle and heat transport in 2D interchange‐dominated electrostatic ExB turbulence in a sheath‐limited scrape‐off layer

Coosemans

Dekeyser

Baelmans

2022

Contributions to Plasma Physics

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In this paper, a self‐consistent model for the average radial turbulent transport of heat and particles in 2D anisothermal interchange‐dominated electrostatic ExB drift turbulence in sheath‐limited scrape‐off layers is presented. Diffusion models are used for the turbulent particle and heat fluxes, in which the transport coefficients scale with the square root of the turbulent kinetic energy (k⊥). The interchange drive proves to be the main source of turbulent kinetic energy, while the sheath term provides the main sink. These observations are qualitatively the same as for the isothermal case studied earlier. An analytical relation for the interchange term is derived, showing that the turbulent ExB thermal energy flux is the direct driver for k⊥ through the interchange source. A series decomposition of the sheath term in the k⊥ equation shows it includes a sink contribution that was also present in the isothermal case, but also a new source due to the sheath‐driven conducting‐wall (SCW) instability caused by electron temperature fluctuations. Using a simple regression model to close the total sheath term, a closed model for the turbulent transport is obtained. The interchange drive due to the ExB energy flux leads to a self‐saturation mechanism in the model, where the gradients and turbulence intensity increase until a sufficient transport level is reached to carry the power and particles across the field lines to find a balance with the sheath sink. An implementation of this model in a 1D mean‐field code approximates the profiles of the turbulence simulations with remarkable accuracy in part of the parameter space, while the error increases in parameter regimes where the relative importance of the SCW term is varied.

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Self-consistent cross-field transport model for core and edge plasma transport

Cited by 21 publications

References 117 publications

A self‐consistent κ‐model for anomalous transport due to electrostatic, interchange‐dominated E × B drift turbulence in the scrape‐off layer and implementation in SOLPS‐ITER

A self‐consistent κ‐model for anomalous transport due to electrostatic, interchange‐dominated E × B drift turbulence in the scrape‐off layer and implementation in SOLPS‐ITER

Validation of edge turbulence codes against the TCV-X21 diverted L-mode reference case

A self‐consistent mean‐field model for turbulent particle and heat transport in 2D interchange‐dominated electrostatic ExB turbulence in a sheath‐limited scrape‐off layer

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