Comparisons of the Plasma Performance of Future Thailand Tokamak using Various External Heating Schemes

Buaruk, Suphachok; Makmool, Thanaphan; Promping, Jiraporn; Onjun, T.; Sangaroon, Siriyaporn; Wisitsorasak, Apiwat; García, J.; Chatthong, Boonyarit

doi:10.1585/pfr.14.3403153

Cited by 7 publications

(3 citation statements)

References 11 publications

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“…Our simulations consider the scenario where hydrogen gas is injected into the tokamak via SMBI, and it is assumed that this injection takes place at the midplane of the tokamak on the low-field side (LFS). The initial profiles for the plasma density and temperatures are ob-tained from a CRONOS integrated predictive simulation that numerically investigates the Ohmic phase of the TT-1 plasma [27]. The electron density near the magnetic axis is estimated to be approximately 2 × 10 19 m −3 , while the temperatures of the electrons and ions at the core are approximately 2500 eV and 750 eV, respectively.…”

Section: Simulation Results and Discussionmentioning

confidence: 99%

Computational Study of the Supersonic Molecular Beam Injection in Thailand Tokamak-1 based on the 2D Fluid Model

RONGPUIT,

WISITSORASAK,

PROMPING

2024

Plasma and Fusion Research

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The successful operation of a tokamak requires effective and appropriate methods of plasma fueling. In the development plan for Thailand Tokamak-1 (TT-1), the use of supersonic molecular beam injection (SMBI) has been proposed as a method that can more effectively and deeply deliver fueling gas compared to the gas puffing method. In this study, we used 2D fluid simulation to investigate the impact of SMBI on plasma transport in TT-1. Our model incorporated the continuity equations, energy balance equations, momentum equation, continuity of fuel equations, and momentum equation of fuel. BOUT++ is then used to solve these equations by a finite difference method with the field-aligned coordinates in the edge region of the tokamak. Our simulation results showed that when hydrogen fuel gas is injected into the plasma via SMBI from the low-field side at the speed in the range of 600 -1200 m/s, the electron density in the edge region locally increases due to dissociation and ionization in the region where the fuel gas meets the plasma. This subsequently leads to a decrease in the ion and electron temperatures. The increased density then spreads throughout the plasma volume within approximately 10 ms. Increasing the injection speed leads to a deeper penetration length for the fuel deposition. c

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Section: Simulation Results and Discussionmentioning

confidence: 99%

Computational Study of the Supersonic Molecular Beam Injection in Thailand Tokamak-1 based on the 2D Fluid Model

RONGPUIT,

WISITSORASAK,

PROMPING

2024

Plasma and Fusion Research

Self Cite

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“…Neumann boundary conditions are employed for other evolving variables. The initial profiles of n e , T e , T i were taken from the CRONOS simulation of TT-1 plasma [1]. There is no the fuel molecule and atoms inside the tokamak at the beginning.…”

Section: Methodsmentioning

confidence: 99%

“…Some components of TT-1 are adopted from the HT-6M tokamak, while most components and several subsystems, such as diagnostic tools, are new. In the initial phase of the operation of TT-1, the hydrogen plasma will be only heated by Ohmic heating, without external heating [1]. It will also rely on the gas puff (GP) for fueling the plasma.…”

Section: Introductionmentioning

confidence: 99%

Preliminary study of supersonic molecular beam injection in Thailand Tokamak-1 using 3D fluid model

Rongpuit

Wisitsorasak

Promping³

2023

J. Phys.: Conf. Ser.

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Successful operation of a tokamak relies on effective and appropriate methods of plasma fueling. The development plan of Thailand Tokamak-1 (TT-1) will employ the supersonic molecular beam injection (SMBI) which delivers the fueling gas more effectively and deeper than the gas puffing method. In this work, we study the effect of SMBI on the plasma transport of TT-1 plasma by using 3D fluid simulation. The model includes the continuity equation, energy balance equation, momentum equation, continuity of fuel equation, and momentum of fuel. BOUT++ is then used to solve these equations by a finite difference method with the field-aligned coordinates in the edge region. The simulation shows that when hydrogen fuel gas is by the SMBI method from the low-field side into the plasma with a speed of 1000 m/s, the electron density in the edge locally rises as a result of the dissociation and ionization. The ion and electron temperatures then drop. After that, the density spread over the whole plasma volume within about 10 ms. When the injection speed increases, it results in a deeper penetration length of the fuel deposition.

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Fast-ion orbit analysis in Thailand Tokamak-1

Paenthong

Wisitsorasak

Sangaroon

et al. 2022

Fusion Engineering and Design

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Comparisons of the Plasma Performance of Future Thailand Tokamak using Various External Heating Schemes

Cited by 7 publications

References 11 publications

Computational Study of the Supersonic Molecular Beam Injection in Thailand Tokamak-1 based on the 2D Fluid Model

Computational Study of the Supersonic Molecular Beam Injection in Thailand Tokamak-1 based on the 2D Fluid Model

Preliminary study of supersonic molecular beam injection in Thailand Tokamak-1 using 3D fluid model

Fast-ion orbit analysis in Thailand Tokamak-1

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