图 1  托卡马克磁约束聚变装置截面结构

Fig. 1.  Power exhaust on tokamak plasma cross-section.

图 2  刮削层-偏滤器区域等离子体热流通道(沿磁力线方向)与主要反应

Fig. 2.  Heat flux flowing along the field line and the main reactions in scrape-off layer (SOL) and divertor region.

图 3  氖气注入偏滤器在沿磁力线方向形成的源剖面 $ {S}_{{{\mathrm{N}}{\mathrm{e}}}^{0}} $

Fig. 3.  The source profile $ {S}_{{{\mathrm{N}}{\mathrm{e}}}^{0}} $ of neon injection into divertor

图 4  刮削层-偏滤器碳杂质含量的影响　(a)抬升上游等离子体密度触发偏滤器脱靶; (b)氖杂质注入偏滤器脱靶. 蓝色曲线表示靶板上电流$ {J}_{{\mathrm{s}}{\mathrm{a}}{\mathrm{t}}, {\mathrm{t}}{\mathrm{a}}{\mathrm{r}}{\mathrm{g}}{\mathrm{e}}{\mathrm{t}}} $, 红色曲线表示靶板上电子温度, 碳杂质含量$ {f}_{{\mathrm{C}}} $分别为0, 1%和3%

Fig. 4.  The effect of carbon concentration in SOL and divertor region on two different divertor detachment regimes: (a) Density ramp induced detachment; (b) neon injection induced detachment. The blue curves and red curves represent the current and the electron temperature on the divertor target (three carbon concentrations used in simulations are 0, 1%, and 3%).

图 5  刮削层-偏滤器碳杂质含量($ {f}_{{\mathrm{C}}}=0, {\mathrm{ }}1{\mathrm{{\text{%}}}}{\mathrm{ }}, 3{\mathrm{{\text{%}}}} $)对平行方向上密度(氘分子、电离态氘分子、氘原子与氘离子)以及对辐射功率的影响 (a), (c)上游等离子体密度抬升至$ {n}_{{\mathrm{e}}, {\mathrm{u}}{\mathrm{p}}}={0.11\times 10}^{20}\;{{\mathrm{m}}}^{-3} $时的剖面; (b), (d) 氖杂质注入通量为$ {6.7\times 10}^{20}\;{\mathrm{p}}{\mathrm{a}}{\mathrm{r}}{\mathrm{t}}{\mathrm{s}}/{\mathrm{s}} $时的剖面, 靶板位于45 m处(由于氘粒子和碳杂质主要分布在靠近靶板的区域, 因此图中只给出了靠近靶板的平行剖面, 即42—45 m)

Fig. 5.  The effect of carbon concentration (0, 1%, and 3%) on the parallel density and radiation profiles in two detachment regimes: (a), (c) The density and radiation in density ramp induced detachment ($ {n}_{{\mathrm{e}}, {\mathrm{u}}{\mathrm{p}}}={0.11\times 10}^{20}\;{{\mathrm{m}}}^{-3} $); (b), (d) the density and radiation in neon injection induced detachment (neon injection flux equal to $ {6.7\times 10}^{20}\;{\mathrm{p}}{\mathrm{a}}{\mathrm{r}}{\mathrm{t}}{\mathrm{s}}/{\mathrm{s}} $). The parallel profile is 42–45 m (the target located at 45 m).

图 6  抬升密度和偏滤器氖杂质注入两种脱靶过程中的平行方向上密度(氘分子、电离态氘分子、氘原子与氘离子)以及辐射功率(氘与碳) (a), (c)刮削层上游电子密度在脱靶前$ {n}_{{\mathrm{e}}, {\mathrm{u}}{\mathrm{p}}}={0.08\times 10}^{20}\;{{\mathrm{m}}}^{-3} $、脱靶开始$ {n}_{{\mathrm{e}}, {\mathrm{u}}{\mathrm{p}}}={0.10\times 10}^{20}\;{{\mathrm{m}}}^{-3} $与脱靶后$ {n}_{{\mathrm{e}}, {\mathrm{u}}{\mathrm{p}}}=0.145\times $$ 10^{20}\;{{\mathrm{m}}}^{-3} $时的剖面; (b), (d)氖杂质注入前, 以及杂质注入通量为$ {3.0\times 10}^{20}\;{\mathrm{p}}{\mathrm{a}}{\mathrm{r}}{\mathrm{t}}{\mathrm{s}}/{\mathrm{s}} $, $ {12.5\times 10}^{20}\;{\mathrm{p}}{\mathrm{a}}{\mathrm{r}}{\mathrm{t}}{\mathrm{s}}/{\mathrm{s}} $时的剖面, 图中碳杂质含量都为3%, 靶板位于45 m处 (由于氘粒子和碳杂质主要分布在靠近靶板的区域, 图中只给出了靠近靶板的剖面, 即42—45 m)

Fig. 6.  Comparison of the parallel density and radiation profiles in two detachment regimes: (a), (c) The density and radiation in density ramp induced detachment ($ {n}_{{\mathrm{e}}, {\mathrm{u}}{\mathrm{p}}}={0.08\times 10}^{20}\;{{\mathrm{m}}}^{-3} $, $ {0.10\times 10}^{20}\;{{\mathrm{m}}}^{-3}, $ and $ {0.145\times 10}^{20}\;{{\mathrm{m}}}^{-3} $); (b), (d) the density and radiation in neon injection induced detachment (neon injection flux equal to $ \text{0 parts/s} $, $ {3.0\times 10}^{20}\;{\mathrm{p}}{\mathrm{a}}{\mathrm{r}}{\mathrm{t}}{\mathrm{s}}/{\mathrm{s}}, $ and $ {12.5\times 10}^{20}\;{\mathrm{p}}{\mathrm{a}}{\mathrm{r}}{\mathrm{t}}{\mathrm{s}}/{\mathrm{s}} $), carbon concentration equal to 3%; the parallel profile is 42–45 m (the target located at 45 m).

图 8  (a)上游密度抬升与(b)偏滤器注氖气两种脱靶过程中, 氘原子、氘分子、电离态氘分子与等离子体相互作用造成的等离子体动量损失与上游等离子体动量的比值, 即等离子体动量损失因子; (c)上游密度抬升与(d)偏滤器注氖气两种脱靶中, 氘粒子、碳杂质与氖杂质辐射造成的等离子体能量损失与上游等离子体能量的比值, 即等离子体能量损失因子, 碳含量为3%

Fig. 8.  Momentum loss factor caused by different types of collisional reactions during (a) density ramp induced detachment and (b) neon injection induced detachment; heat loss factor caused by radiations of different particle species during (c) density ramp induced detachment and (d) neon injection induced detachment (carbon concentration equal to 3%).

图 7  平行方向上从刮削层(0—24 m), 通过X点(24 m)氘靶板(45 m)的氖杂质密度和辐射功率(氖杂质注入通量为$ {3.0\times 10}^{20}\;{\mathrm{p}}{\mathrm{a}}{\mathrm{r}}{\mathrm{t}}{\mathrm{s}}/{\mathrm{s}} $, 上游电子密度$ {n}_{{\mathrm{e}}, {\mathrm{u}}{\mathrm{p}}}=0.08\times 10^{20}\;{{\mathrm{m}}}^{-3} $, 碳杂质含量为3%)

Fig. 7.  Neon density and radiation profile along the parallel direction from SOL to the target (neon injection flux equal to $ {3.0\times 10}^{20}\;{\mathrm{p}}{\mathrm{a}}{\mathrm{r}}{\mathrm{t}}{\mathrm{s}}/{\mathrm{s}} $, $ {n}_{{\mathrm{e}}, {\mathrm{u}}{\mathrm{p}}}={0.08\times 10}^{20}\;{{\mathrm{m}}}^{-3} $, carbon concentration equal to 3%).