N. Rivals , N. Fedorczak , P. Tamain , H. Bufferand , G. Ciraolo , H. Yang , Y. Marandet , J. Gaspar , E. Geulin , J.P. Gunn , C. Guillemaut , J. Morales , P. Manas , R. Nouailletas , M. Dimitrova , J. Cavalier , J. Svoboda , H. Reimerdes , D. Brida , T. Lunt , M. Bernert
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At the same time, core conditions are significantly improved. These scenarios were successfully controlled in WEST using an interferometry line-of-sight passing through the X-point. Interpretative modeling of these discharges with the SOLEDGE3X-EIRENE code reveals that a physics mechanism needed to stabilize WEST nitrogen XPRs is not present when driving the simulations at constant power. 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引用次数: 0
摘要
在2023年和2024年的实验活动期间,在WEST托卡马克实验中使用氮气种子获得了X点辐射器(XPR)状态。这些实验表明,在X点附近形成了一个稳定的环形辐射环,这与在JET、ASDEX-Upgrade、TCV和COMPASS等其他装置中的观测结果类似。在西半球,这一机制的出现与分流器等离子体从热态向冷态和高密度状态的急剧转变有关,粒子通量增加,表明等离子体没有脱离。与此同时,核心条件得到显著改善。利用穿过 X 点的干涉测量视线,WEST 成功地控制了这些情况。利用 SOLEDGE3X-EIRENE 代码对这些放电进行的解释性建模显示,在以恒定功率驱动模拟时,并不存在稳定 WEST 氮 XPR 所需的物理机制。相反,通过增加 XPR 开始时的注入功率,可以获得稳定的 XPR,以表示 W 污染的减少,这凸显了描述等离子体动力学和进行综合核边模拟的必要性。
Experiments and SOLEDGE3X modeling of dissipative divertor and X-point Radiator regimes in WEST
X-Point Radiator (XPR) regimes have been obtained in WEST tokamak experiments with nitrogen seeding during the experimental campaigns of 2023 and 2024. These experiments showed the formation of a stable toroidal radiating ring near the X-point, similar to observations in other devices such as JET, ASDEX-Upgrade, TCV, and COMPASS. In WEST, the onset of this regime is associated with a sharp transition of the divertor plasma from hot to cold and dense conditions, with increased particle fluxes, indicating that the plasma is not detached. At the same time, core conditions are significantly improved. These scenarios were successfully controlled in WEST using an interferometry line-of-sight passing through the X-point. Interpretative modeling of these discharges with the SOLEDGE3X-EIRENE code reveals that a physics mechanism needed to stabilize WEST nitrogen XPRs is not present when driving the simulations at constant power. On the contrary, a stable XPR can be obtained by increasing the power injected at the time of the XPR onset to represent the reduction of W contamination, highlighting the need to describe the plasma dynamics and go toward integrated core–edge 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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