Your search keyword '"Coosemans, Reinart"' showing total 10 results

1. Turbulent kinetic energy in 2D isothermal interchange-dominated scrape-off layer ExB drift turbulence: Governing equation and relation to particle transport

Author

Coosemans, Reinart, Dekeyser, Wouter, and Baelmans, Martine

Subjects

Physics - Plasma Physics, Physics - Fluid Dynamics

Abstract

This paper studies the turbulent kinetic energy ($k_\perp$) in 2D isothermal electrostatic interchange-dominated ExB drift turbulence in the scrape-off layer and its relation to particle transport. An evolution equation for the former is analytically derived from the underlying turbulence equations. Evaluating this equation shows that the dominant source for the turbulent kinetic energy is due to interchange drive, while the parallel current loss to the sheath constitutes the main sink. Perpendicular transport of the turbulent kinetic energy seems to play a minor role in the balance equation. Reynolds stress energy transfer also seems to be negligible, presumably because no significant shear flow develops under the given assumptions of isothermal sheath-limited conditions in the open field line region. The interchange source of the turbulence is analytically related to the average turbulent ExB energy flux, while a regression analysis of TOKAM2D data suggests a model that is linear in the turbulent kinetic energy for the sheath loss. A similar regression analysis yields a diffusive model for the average radial particle flux, in which the anomalous diffusion coefficient scales with the square root of the turbulent kinetic energy. Combining these three components, a closed set of equations for the mean-field particle transport is obtained, in which the source of the turbulence depends on mean flow gradients and $k_\perp$ through the particle flux, while the turbulence is saturated by parallel losses to the sheath. Implementation of this new model in a 1D mean-field code shows good agreement with the original TOKAM2D data over a range of model parameters., Comment: This article may be downloaded for personal use only. Any other use requires prior permission of the author and AIP Publishing. This article appeared in Physics of Plasmas 28, 012302 (2021) and may be found at https://doi.org/10.1063/5.0024479

Published

2019

2. Mean-field transport equations and energy theorem for plasma edge turbulent transport

Author

Coosemans, Reinart, primary, Dekeyser, Wouter, additional, and Baelmans, Martine, additional

Published

2024

3. Progress in the development of the ITER baseline scenario in TCV

Author

Labit, Benoit, primary, Sauter, Olivier, additional, Pütterich, Thomas, additional, Bagnato, Filippo, additional, Camenen, Yann, additional, Coda, Stefano, additional, Contré, Cassandre, additional, Coosemans, Reinart, additional, Eriksson, Frida, additional, Février, Olivier, additional, Fransson, Emil, additional, Karpushov, Alexander N, additional, Krutkin, Oleg, additional, Marchioni, Stefano, additional, Merle, Antoine, additional, Pau, Alessandro, additional, Piron, Lidia, additional, Vallar, Matteo, additional, Van Mulders, Simon, additional, and Voitsekhovitch, Irina, additional

Published

2024

4. 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

Author

Dekeyser, Wouter, Coosemans, Reinart, Carli, Stefano, and Baelmans, Martine

Subjects

interchange turbulence, plasma edge modeling, anomalous transport, SOLPS-ITER

Abstract

ispartof: Contributions To Plasma Physics vol:62 issue:5-6 status: Published online

Published

2022

5. 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

Author

Dekeyser, Wouter, primary, Coosemans, Reinart, additional, Carli, Stefano, additional, and Baelmans, Martine, additional

Published

2022

6. 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

Author

Coosemans, Reinart, primary, Dekeyser, Wouter, additional, and Baelmans, Martine, additional

Published

2022

7. Bayesian maximum a posteriori‐estimation of κ turbulence model parameters using algorithmic differentiation in SOLPS‐ITER

Author

Carli, Stefano, primary, Dekeyser, Wouter, additional, Blommaert, Maarten, additional, Coosemans, Reinart, additional, Van Uytven, Wim, additional, and Baelmans, Martine, additional

Published

2021

8. Bayesian maximum a posteriori‐estimation of κ turbulence model parameters using algorithmic differentiation in SOLPS‐ITER.

Author

Carli, Stefano, Dekeyser, Wouter, Blommaert, Maarten, Coosemans, Reinart, Van Uytven, Wim, and Baelmans, Martine

Subjects

AUTOMATIC differentiation, TURBULENCE, NONLINEAR regression, FINITE differences, DIFFUSION coefficients, PLASMA turbulence

Abstract

Radial anomalous diffusion coefficients are among the largest sources of uncertainty in mean‐field plasma‐edge codes such as SOLPS‐ITER. These coefficients are machine, scenario, and space‐dependent, thus hampering the predictive and interpretive capability of these codes. In fact, modellers usually adjust these coefficients manually, based on expert judgement or on large, computationally expensive, parameter scans. Matching data from various diagnostics, each with their own experimental uncertainties, additionally complicates the problem of finding a good parameter set. In addition, standard non‐linear regression techniques have shown to become prohibitive for expensive plasma‐edge simulations with many unknown parameters, as gradient calculation was based on finite differences. In this paper, we apply algorithmic differentiation (AD) as an efficient and more accurate alternative for gradient calculation in large, continuously developed codes as SOLPS‐ITER. In addition, the lack of uncertainty information and danger of data overfitting, key limitations of regression techniques, are overcome by combining data and uncertainties from different diagnostics in a Bayesian framework. We implement for the first time such a Bayesian inference framework into SOLPS‐ITER, using gradient‐based optimization with gradients obtained through tangent AD to find the maximum a posteriori (MAP) values of the parameters. The recently developed κ turbulence model is employed to limit the number of unknown parameters compared to full spatial profiles of diffusion coefficients. The Bayesian MAP‐estimation is compared to standard regression techniques on a small‐scale tokamak. We adopt fictitious experimental data obtained from a reference SOLPS‐ITER solution with artificial measurement noise. [ABSTRACT FROM AUTHOR]

Published

2022

9. Interchange-turbulence-based radial transport model for SOLPS-ITER: A COMPASS case study

Author

Carli, Stefano, primary, Dekeyser, Wouter, additional, Coosemans, Reinart, additional, Dejarnac, Renaud, additional, Komm, Michael, additional, Dimitrova, Miglena, additional, Adámek, Jiří, additional, Bílková, Petra, additional, and Böhm, Petr, additional

Published

2020

10. A new mean-field plasma edge transport model based on turbulent kinetic energy and enstrophy

Author

Coosemans, Reinart, primary, Dekeyser, Wouter, additional, and Baelmans, Martine, additional

Published

2020