Development of MMM95 transport model for predicting deuteron and carbon ion densities evolution in H-mode tokamak

Wannapa Buangam; Sujin Suwanna; Thawatchai Onjun

Development of MMM95 transport model for predicting deuteron and carbon ion densities evolution in H-mode tokamak

Wannapa Buangam, Sujin Suwanna, Thawatchai Onjun

Research output: Contribution to journal › Article › peer-review

Abstract

The BALDUR code is used for predicting core profiles in H-mode plasma, by employing a combination of the MMM95 anomalous transport model and the NCLASS neoclassical transport model. The pedestal temperature and density of Deuteron and Carbon are taken from the experiment as a boundary conditions in the simulations. The simulated profiles, including those of the electron and ion temperature, electron, Deuteron and Carbon ion density profiles, are compared with the corresponding experimental data. The multi-parameter optimization is used for obtaining the most suitable coefficients for hydrogenic and impurity diffusion coefficient for new MMM95 transport model. This new set of coefficients for hydrogenic and impurity transport can improve the prediction of the electron and ion temperature, electron, Deuteron and Carbon ion density profiles of JET H-mode discharges within the RMS errors of 13%.

Original language	English
Pages (from-to)	588-597
Number of pages	10
Journal	Chiang Mai Journal of Science
Volume	47
Issue number	3
Publication status	Published - 2020
Externally published	Yes

Keywords

H-mode
Impurity transport in tokamak
MMM95

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Cite this

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title = "Development of MMM95 transport model for predicting deuteron and carbon ion densities evolution in H-mode tokamak",

abstract = "The BALDUR code is used for predicting core profiles in H-mode plasma, by employing a combination of the MMM95 anomalous transport model and the NCLASS neoclassical transport model. The pedestal temperature and density of Deuteron and Carbon are taken from the experiment as a boundary conditions in the simulations. The simulated profiles, including those of the electron and ion temperature, electron, Deuteron and Carbon ion density profiles, are compared with the corresponding experimental data. The multi-parameter optimization is used for obtaining the most suitable coefficients for hydrogenic and impurity diffusion coefficient for new MMM95 transport model. This new set of coefficients for hydrogenic and impurity transport can improve the prediction of the electron and ion temperature, electron, Deuteron and Carbon ion density profiles of JET H-mode discharges within the RMS errors of 13%.",

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author = "Wannapa Buangam and Sujin Suwanna and Thawatchai Onjun",

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journal = "Chiang Mai Journal of Science",

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T1 - Development of MMM95 transport model for predicting deuteron and carbon ion densities evolution in H-mode tokamak

AU - Buangam, Wannapa

AU - Suwanna, Sujin

AU - Onjun, Thawatchai

PY - 2020

Y1 - 2020

N2 - The BALDUR code is used for predicting core profiles in H-mode plasma, by employing a combination of the MMM95 anomalous transport model and the NCLASS neoclassical transport model. The pedestal temperature and density of Deuteron and Carbon are taken from the experiment as a boundary conditions in the simulations. The simulated profiles, including those of the electron and ion temperature, electron, Deuteron and Carbon ion density profiles, are compared with the corresponding experimental data. The multi-parameter optimization is used for obtaining the most suitable coefficients for hydrogenic and impurity diffusion coefficient for new MMM95 transport model. This new set of coefficients for hydrogenic and impurity transport can improve the prediction of the electron and ion temperature, electron, Deuteron and Carbon ion density profiles of JET H-mode discharges within the RMS errors of 13%.

AB - The BALDUR code is used for predicting core profiles in H-mode plasma, by employing a combination of the MMM95 anomalous transport model and the NCLASS neoclassical transport model. The pedestal temperature and density of Deuteron and Carbon are taken from the experiment as a boundary conditions in the simulations. The simulated profiles, including those of the electron and ion temperature, electron, Deuteron and Carbon ion density profiles, are compared with the corresponding experimental data. The multi-parameter optimization is used for obtaining the most suitable coefficients for hydrogenic and impurity diffusion coefficient for new MMM95 transport model. This new set of coefficients for hydrogenic and impurity transport can improve the prediction of the electron and ion temperature, electron, Deuteron and Carbon ion density profiles of JET H-mode discharges within the RMS errors of 13%.

KW - H-mode

KW - Impurity transport in tokamak

KW - MMM95

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M3 - Article

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SN - 0125-2526

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EP - 597

JO - Chiang Mai Journal of Science

JF - Chiang Mai Journal of Science

IS - 3

ER -

Development of MMM95 transport model for predicting deuteron and carbon ion densities evolution in H-mode tokamak

Abstract

Keywords

UN SDGs

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