Andreas Holm , Robert S. Wilcox , Jonathan H. Yu , Thomas D. Rognlien , Marvin E. Rensink , Filippo Scotti , Roberto Maurizio , Steve L. Allen , Wilkie Choi , Anothony W. Leonard , Morgan W. Shafer , Mathias Groth , Adam McLean
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引用次数: 0
摘要
使用多流体代码 UEDGE 对 DIII-D 中的障板长脚分流器进行的边缘等离子体模拟表明,脱离前沿的位置受限于沿低场侧(LFS)障板的泵管位置。对包括本征碳和种子氖在内的 12.5 兆瓦氘等离子体进行了包括磁漂移和 E×B 漂移在内的模拟,以评估 LFS 分流泵的最佳位置,从而在目标和 X 点之间形成稳定的脱离前沿。模拟中的辐射前沿位置被认为是脱离前沿的指示位置,可通过沿 LFS 挡板将泵管位置移至目标上游来控制泵和 X 点之间在 H 模式进入的有利磁场方向上的位置。在不利磁场方向,径向 Eθ×B 漂移流向泵表面,有效清除注入的氘气体,限制辐射锋位置对气体注入率的敏感性。在 UEDGE 模拟中还发现,抽气速率和漂移方向对抽气效率的作用也会影响分流器等离子体条件和脱离前沿位置。
Modeling a divertor with mid-leg pumping for high-power H-mode scenarios in DIII-D considering E × B drift flows
Edge-plasma simulations of a baffled, long-legged divertor in DIII-D, performed using the multi-fluid code UEDGE, indicate that the position of the detachment front is constrained to the location of the pump duct along the low-field side (LFS) baffle. Simulations including magnetic and drifts were performed for 12.5 MW deuterium plasmas including intrinsic carbon and seeded neon to assess the optimal location of the LFS divertor pump to create a stable detachment front between the target and the X-point. The radiation front position in the simulations, taken to be indicative of the detachment front, can be controlled between the pump and X-point in the favorable magnetic field direction for H-mode access by moving the pump duct location upstream of the target along the LFS baffle. In the unfavorable magnetic field direction, the radial drift flows are directed towards the pumping surface, efficiently removing the injected deuterium gas and limiting the sensitivity of the radiation front location to the gas injection rate. The role of pumping rate and drift direction on the pumping efficiency are also found to affect the divertor plasma conditions and detachment front location in UEDGE simulations.
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The open-access journal Nuclear Materials and Energy is devoted to the growing field of research for material application in the production of nuclear energy. Nuclear Materials and Energy publishes original research articles of up to 6 pages in length.
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