H. Reimerdes , C. Theiler , M. Bernert , B.P. Duval , O. Février , S. Gorno , D. Hamm , K. Lee , O. Pan , A. Perek , L. Simons , G. Sun , A. Thornton , K. Verhaegh , Y. Wang , C. Wüthrich , M. Zurita , the TCV team , the EUROfusion tokamak exploitation team
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引用次数: 0
Abstract
TCV’s operating regime with an X-point radiator (XPR) has been broadened by changing the magnetic geometry. XPRs have properties that could make them an attractive power exhaust solution for fusion reactors. These include the conversion of a high fraction of exhaust power into radiation. TCV had previously accessed the XPR regime only with difficulties, as predicted for plasmas where radiative losses are dominated by carbon impurities, that are ubiquitous in TCV. Guided by this theoretical model of the XPR, recent experiments employed TCV’s configurational versatility to demonstrate that XPR access can be facilitated by introducing a second X-point in the vicinity of the separatrix. This configuration, which has a snowflake-minus topology, features a particularly long magnetic connection length from the region just above the X-point to the outer midplane together with a wide geometrical interface with the private flux region that reaches high neutral pressures. Transitioning to this configuration in a high-power H-mode leads to a shift in the radiating region across the separatrix from the divertor to a volume above the X-point, i.e. within the last closed flux surface (LCFS). This displacement of the radiating region is co-incident with the disappearance of edge localised modes (ELMs), while retaining H-mode confinement, a behaviour only, to date, observed in devices with metallic walls. In contrast to observations in these other devices, on TCV, the primary strike points in these configurations remain attached. Detailed measurements of the plasma kinetic parameters inside and outside of the separatrix now challenge the models for access and stability of the XPR and ELMs alike.
TCV 的 X 点辐射器 (XPR) 运行机制已通过改变磁性几何形状而得到拓宽。XPR 的特性可使其成为聚变反应堆的一种有吸引力的功率排气解决方案。其中包括将高比例的排气功率转化为辐射。TCV 先前进入 XPR 状态时遇到了困难,因为根据预测,等离子体的辐射损失主要由碳杂质造成,而碳杂质在 TCV 中无处不在。在这一 XPR 理论模型的指导下,最近的实验利用 TCV 的构型多样性证明,在分离矩阵附近引入第二个 X 点可以促进 XPR 的进入。这种构型具有雪花减拓扑结构,其特点是从 X 点上方区域到外部中平面的磁连接长度特别长,同时与达到高中性压力的私有磁通区域具有宽阔的几何界面。在高功率 H 模式下过渡到这种配置会导致辐射区域从分流器横跨分离矩阵转移到 X 点上方,即最后一个封闭磁通面(LCFS)内。辐射区域的这种移动与边缘局部模式(ELM)的消失同时发生,同时保留了 H 模式约束,迄今为止,只有在具有金属壁的设备中才能观察到这种行为。与在这些其他装置中观察到的情况不同,在 TCV 上,这些配置中的主要撞击点仍然是附着的。对分离矩阵内外等离子体动力学参数的详细测量结果,对 XPR 和 ELM 的进入和稳定性模型提出了挑战。
期刊介绍:
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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