LH-transition initiation and dynamics in a conventional tokamak

PROCEEDINGS OF THE INTERNATIONAL CONFERENCE ON ADVANCES AND APPLICATIONS IN PLASMA PHYSICS (AAPP 2019) Pub Date : 2019-11-26 DOI:10.1063/1.5135475

G. Abdullina, L. Askinazi, A. Belokurov, V. Bulanin, L. Chôné, A. Gurchenko, E. Gusakov, T. Kiviniemi, V. Kornev, S. Krikunov, D. Kouprienko, S. Lashkul, S. Lebedev, S. Leerink, P. Niskala, A. Petrov, A. Tukachinsky, A. Yashin, N. Zhubr

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Abstract

Radial electric field shear is crucial for turbulence suppression and transition to the H-mode, although the high shear value alone may not be sufficient for the LH-transition initiation. Temporal and spatial parameters of shear perturbation, particle source and turbulence parameters are the main factors responsible for LH-transition initiation. Different plasma discharge scenarios in two Ioffe Institute conventional tokamaks are analyzed using the model of plasma density and ion temperature evolution to clear up the role of aforementioned factors.Radial electric field shear is crucial for turbulence suppression and transition to the H-mode, although the high shear value alone may not be sufficient for the LH-transition initiation. Temporal and spatial parameters of shear perturbation, particle source and turbulence parameters are the main factors responsible for LH-transition initiation. Different plasma discharge scenarios in two Ioffe Institute conventional tokamaks are analyzed using the model of plasma density and ion temperature evolution to clear up the role of aforementioned factors.

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传统托卡马克的lh跃迁起始和动力学

径向电场剪切对于湍流抑制和向h模式转变至关重要，尽管仅高剪切值可能不足以引发h -转变。剪切扰动的时空参数、粒子源参数和湍流参数是影响lh跃迁起始的主要因素。利用等离子体密度和离子温度演化模型分析了Ioffe研究所两种常规托卡马克中不同的等离子体放电情况，明确了上述因素的作用。径向电场剪切对于湍流抑制和向h模式转变至关重要，尽管仅高剪切值可能不足以引发h -转变。剪切扰动的时空参数、粒子源参数和湍流参数是影响lh跃迁起始的主要因素。利用等离子体密度和离子温度演化模型分析了Ioffe研究所两种常规托卡马克中不同的等离子体放电情况，明确了上述因素的作用。

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PROCEEDINGS OF THE INTERNATIONAL CONFERENCE ON ADVANCES AND APPLICATIONS IN PLASMA PHYSICS (AAPP 2019)

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