\begin{document}$ {\text{[Kr]4}}{{\text{d}}^{{10}}}{5}{{\text{s}}^{2}}{4}{{\text{f}}^{{14}}}{5}{{\text{p}}^{6}} $\end{document}和亚稳态\begin{document}$ {\text{[Kr]4}}{{\text{d}}^{{10}}}{5}{{\text{s}}^{2}}{4}{{\text{f}}^{{14}}}{5}{{\text{p}}^{5}}{5}{{\text{d}}^{1}} $\end{document}, \begin{document}$ {\text{[Kr]4}}{{\text{d}}^{{10}}}{5}{{\text{s}}^{2}}{4}{{\text{f}}^{{13}}}{5}{{\text{p}}^{6}}{5}{{\text{d}}^{1}} $\end{document}, \begin{document}$ {\text{[Kr]4}}{{\text{d}}^{{10}}}{5}{{\text{s}}^{2}}{4}{{\text{f}}^{{14}}}{5}{{\text{p}}^{5}}{5}{{\text{f}}^{1}} $\end{document}, \begin{document}$ {\text{[Kr]4}}{{\text{d}}^{{10}}}{5}{{\text{s}}^{2}}{4}{{\text{f}}^{{13}}}{5}{{\text{p}}^{6}}{5}{{\text{f}}^{1}} $\end{document}的电子碰撞单电离(EISI)截面. 为了考虑亚稳态离子对电离的贡献, 本文采用了3种模型来确定母离子束中处于长寿命能级的比值. 与Pindzola和Griffin (1997 Phys. Rev. A 56 1654)的理论结果和Stenke等(1995 J. Phys. B: At. Mol. Opt. Phys. 28 2711)实验结果进行比较, 发现在考虑了亚稳态的贡献后本文结果与Stenke等的实验结果吻合得很好."> - 必威体育下载

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    马莉莉, 张世平, 张芳军, 李麦娟, 蒋军, 丁晓彬, 颉录有, 张登红, 董晨钟

    Theoretical investigation of electron-impact ionization of W6+ion

    Ma Li-Li, Zhang Shi-Ping, Zhang Fang-Jun, Li Mai-Juan, Jiang Jun, Ding Xiao-Bin, Xie Lu-You, Zhang Deng-Hong, Dong Chen-Zhong
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    • 采用细致能级扭曲波方法计算了W 6+离子基态 $ {\text{[Kr]4}}{{\text{d}}^{{10}}}{5}{{\text{s}}^{2}}{4}{{\text{f}}^{{14}}}{5}{{\text{p}}^{6}} $ 和亚稳态 $ {\text{[Kr]4}}{{\text{d}}^{{10}}}{5}{{\text{s}}^{2}}{4}{{\text{f}}^{{14}}}{5}{{\text{p}}^{5}}{5}{{\text{d}}^{1}} $ , $ {\text{[Kr]4}}{{\text{d}}^{{10}}}{5}{{\text{s}}^{2}}{4}{{\text{f}}^{{13}}}{5}{{\text{p}}^{6}}{5}{{\text{d}}^{1}} $ , $ {\text{[Kr]4}}{{\text{d}}^{{10}}}{5}{{\text{s}}^{2}}{4}{{\text{f}}^{{14}}}{5}{{\text{p}}^{5}}{5}{{\text{f}}^{1}} $ , $ {\text{[Kr]4}}{{\text{d}}^{{10}}}{5}{{\text{s}}^{2}}{4}{{\text{f}}^{{13}}}{5}{{\text{p}}^{6}}{5}{{\text{f}}^{1}} $ 的电子碰撞单电离(EISI)截面. 为了考虑亚稳态离子对电离的贡献, 本文采用了3种模型来确定母离子束中处于长寿命能级的比值. 与Pindzola和Griffin ( 1997 Phys. Rev. A 561654 )的理论结果和Stenke等( 1995 J. Phys. B: At. Mol. Opt. Phys. 282711 )实验结果进行比较, 发现在考虑了亚稳态的贡献后本文结果与Stenke等的实验结果吻合得很好.
      Due to its unique characteristics, metal tungsten has been selected as the wall material for the tokamak magnetic confinement fusion device. The wall material directly interacts with the plasma for a long time, thus causing tungsten atoms and ions to be sputtered and ionized into different charge states, which then enter the tokamak device as plasma impurities. To ensure stable plasma combustion conditions, highly complex model is currently being used to evaluate the behavior of tungsten impurities and their influence on the tokamak plasma. This requires various high-precision atomic data for tungsten atoms and different ionized states of tungsten ions. Electron collision ionization, as a fundamental atomic physical process, is widely encountered in laboratory and astrophysical plasma environments. The parameters such as electron collision ionization cross-sections and rate coefficients are crucial for plasma radiation transport simulations and state diagnostics. Electron-impact single-ionization (EISI) cross sections of the ground state and metastable state for W 6+ions are calculated by using the level-to-level distorted-wave (LLDW) method. The contributions of direct ionization (DI) cross section and excited autoionization (EA) cross section to the total EISI cross section are primarily considered. Comparison of our calculation results with the experimental data from Stenke et al. (Stenke M, Aichele K, Harthiramani D, Hofmann G, Steidl M, Volpel R, Salzborn E 1995 J. Phys. B: At. Mol. Opt. Phys. 282711 ) reveals that the EISI cross section considering only the ground state is significantly smaller than the experimental result. Therefore, it is imperative to take into account the contribution from the metastable state. To determine the fraction of ions in long-lived energy levels within the parent ion beam, three models are employed. Our results, which include the contribution of metastable states, accord well with the experimental results of Stenke et al. Compared with the theoretical calculation result of Pindzola et al. our calculaiton provides a more comprehensive understanding of the electron-impact single-ionization process for W 6+ions. The comparison is illustrated in the attached figure.
          通信作者:张登红,zhangdh@nwnu.edu.cn
        • 基金项目:国家自然科学基金(批准号: 12364034)和甘肃省科技计划(批准号: 23YFFA0074)资助的课题.
          Corresponding author:Zhang Deng-Hong,zhangdh@nwnu.edu.cn
        • Funds:Project supported by the National Natural Science Foundation of China (Grant No. 12364034) and the Science and Technology Project of Gansu Province, China (Grant No. 23YFFA0074).
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      • Configuration Method 5d 4f 5p 5s 4d
        5p6 FAC 118.28 120.19 166.43 334.88
        MCDF[28] 119.0 120.6 166.8 335.9
        NIST[29] 122.01$ \pm $0.06 122.11$ \pm $0.06
        5p55d1 FAC 81.85 120.45 122.14 164.24
        MCDF[28] 81.95 120.9 122.4 164.2
        下载: 导出CSV

        Configuration Index Level J Energy/eV Lifetimes/s Configuration Index Level J Energy/eV Lifetimes/s
        5p6 0 $ 5{{\mathrm{p}}}_{+}^{4} $ 0 0 30 $ 5{{\mathrm{p}}}_{+}^{3}5{{\mathrm{f}}}_{+}^{1} $ 4 78.81 8.70×10–1
        4f135d1 1 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{d}}}_{-}^{1} $ 2 36.18 2.63×10–1 31 $ 5{{\mathrm{p}}}_{+}^{3}5{{\mathrm{f}}}_{+}^{1} $ 2 79.10 4.12×10–1
        2 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{d}}}_{-}^{1} $ 3 37.44 2.11×10–1 32 $ 5{{\mathrm{p}}}_{-}^{1}5{{\mathrm{f}}}_{-}^{1} $ 3 89.54 7.15×10–5
        3 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{d}}}_{-}^{1} $ 4 37.72 3.38×10–1 33 $ 5{{\mathrm{p}}}_{-}^{1}5{{\mathrm{f}}}_{+}^{1} $ 3 89.61 7.18×10–5
        4 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{d}}}_{+}^{1} $ 6 37.98 6.19×10–2 34 $ 5{{\mathrm{p}}}_{-}^{1}5{{\mathrm{f}}}_{+}^{1} $ 4 89.70 7.00×10–5
        5 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{d}}}_{+}^{1} $ 2 38.29 2.59×10–2 35 $ 5{{\mathrm{p}}}_{-}^{1}5{{\mathrm{f}}}_{+}^{1} $ 2 90.00 6.78×10–5
        6 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{d}}}_{+}^{1} $ 4 38.78 1.26×10–2 4f135f1 36 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{f}}}_{+}^{1} $ 1 75.70 1.23×10+2
        7 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{d}}}_{+}^{1} $ 3 38.94 2.03×10–2 37 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{f}}}_{-}^{1} $ 2 75.72 1.48×10+1
        8 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{d}}}_{+}^{1} $ 5 39.10 2.75×10–2 38 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{f}}}_{-}^{1} $ 6 75.77 1.92×10+4
        9 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{d}}}_{+}^{1} $ 4 39.22 1.10×10–2 39 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{f}}}_{+}^{1} $ 3 75.91 4.47×10+1
        10 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{d}}}_{+}^{1} $ 0 39.41 8.02×10–2 40 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{f}}}_{-}^{1} $ 3 76.12 4.60×10+2
        11 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{d}}}_{-}^{1} $ 2 39.53 5.97×10–3 41 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{f}}}_{-}^{1} $ 4 76.13 6.76×10+1
        12 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{d}}}_{-}^{1} $ 3 40.23 5.14×10–2 42 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{f}}}_{-}^{1} $ 5 76.17 2.11×10+1
        13 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{d}}}_{+}^{1} $ 5 40.52 4.06×10–3 43 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{f}}}_{+}^{1} $ 2 76.18 2.97
        14 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{d}}}_{+}^{1} $ 2 40.79 4.96×10–3 44 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{f}}}_{+}^{1} $ 5 76.20 2.95×10+1
        15 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{d}}}_{+}^{1} $ 3 41.23 4.39×10–3 45 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{f}}}_{+}^{1} $ 6 76.22 1.67×10+1
        16 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{d}}}_{+}^{1} $ 4 41.37 4.69×10–3 46 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{f}}}_{+}^{1} $ 4 76.26 6.77×10+1
        5p55d1 17 $ 5{{\mathrm{p}}}_{+}^{3}5{{\mathrm{d}}}_{-}^{1} $ 1 39.18 3.16×10+1 47 $ 4{{\mathrm{f}}}_{+}^{7}5{{\mathrm{f}}}_{+}^{1} $ 0 76.81 3.36×10–2
        18 $ 5{{\mathrm{p}}}_{+}^{3}5{{\mathrm{d}}}_{-}^{1} $ 3 40.64 5.40×10–1 48 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{f}}}_{+}^{1} $ 1 77.73 1.31×10–2
        19 $ 5{{\mathrm{p}}}_{+}^{3}5{{\mathrm{d}}}_{-}^{1} $ 2 40.69 1.17×10–2 49 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{f}}}_{-}^{1} $ 1 78.01 1.19×10–2
        20 $ 5{{\mathrm{p}}}_{+}^{3}5{{\mathrm{d}}}_{-}^{1} $ 4 40.88 3.15 50 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{f}}}_{-}^{1} $ 5 78.03 1.10×10–2
        21 $ 5{{\mathrm{p}}}_{+}^{3}5{{\mathrm{d}}}_{-}^{1} $ 2 41.76 1.11×10–2 51 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{f}}}_{+}^{1} $ 6 78.11 1.06×10–2
        22 $ 5{{\mathrm{p}}}_{+}^{3}5{{\mathrm{d}}}_{-}^{1} $ 3 43.18 7.07×10–3 52 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{f}}}_{+}^{1} $ 2 78.16 1.11×10–2
        23 $ 5{{\mathrm{p}}}_{-}^{1}5{{\mathrm{d}}}_{-}^{1} $ 2 51.40 4.05×10–5 53 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{f}}}_{+}^{1} $ 3 78.31 1.07×10–2
        24 $ 5{{\mathrm{p}}}_{-}^{1}5{{\mathrm{d}}}_{+}^{1} $ 2 52.83 4.30×10–5 54 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{f}}}_{-}^{1} $ 3 78.40 1.10×10–2
        25 $ 5{{\mathrm{p}}}_{-}^{1}5{{\mathrm{d}}}_{+}^{1} $ 3 53.44 3.42×10–5 55 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{f}}}_{-}^{1} $ 2 78.44 9.91×10–3
        5p55f1 26 $ 5{{\mathrm{p}}}_{+}^{3}5{{\mathrm{f}}}_{-}^{1} $ 2 77.81 2.43 56 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{f}}}_{+}^{1} $ 4 78.47 1.07×10–2
        27 $ 5{{\mathrm{p}}}_{+}^{3}5{{\mathrm{f}}}_{-}^{1} $ 4 78.11 1.75×10+1 57 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{f}}}_{-}^{1} $ 4 78.50 1.04×10–2
        28 $ 5{{\mathrm{p}}}_{+}^{3}5{{\mathrm{f}}}_{+}^{1} $ 3 78.31 1.13 58 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{f}}}_{+}^{1} $ 5 78.50 1.06×10–2
        29 $ 5{{\mathrm{p}}}_{+}^{3}5{{\mathrm{f}}}_{-}^{1} $ 3 78.70 9.02×10–1 59 $ 4{{\mathrm{f}}}_{-}^{5}5{{\mathrm{f}}}_{-}^{1} $ 0 86.47 3.52×10–4
        下载: 导出CSV

        Configurations Energy range
        (Model 1)/eV
        Energy range
        (Model 2)/eV
        [0, 118] [118, 1000] [0, 118] [118, 1000]
        5p6 0 0.35 0 0.31
        4f135d1 0.40 0.10 0.35 0.10
        5p55d1 0.40 0.11 0.35 0.12
        5p55f1 0.10 0.22 0.15 0.23
        4f135f1 0.10 0.22 0.15 0.24
        下载: 导出CSV

        Level index Energy range/eV Level index Energy range/eV
        [0, 118] [118, 1000] [0, 118] [118, 1000]
        0 0 0.31000 30 0.00800 0.02300
        1 0.04468 0.00625 31 0.00800 0.02300
        2 0.04468 0.00625 32 0.00800 0.02300
        3 0.04468 0.00625 33 0.00800 0.02300
        4 0.04468 0.00625 34 0.00800 0.02300
        5 0.04469 0.00625 35 0.00800 0.02300
        6 0.04469 0.00625 36 0.00333 0.01000
        7 0.04469 0.00625 37 0.00333 0.01000
        8 0.04469 0.00625 38 0.00333 0.01000
        9 0.04469 0.00625 39 0.00333 0.01000
        10 0.04469 0.00625 40 0.00333 0.01000
        11 0.04469 0.00625 41 0.00333 0.01000
        12 0.04469 0.00625 42 0.00333 0.01000
        13 0.04469 0.00625 43 0.00333 0.01000
        14 0.04469 0.00625 44 0.00333 0.01000
        15 0.04469 0.00625 45 0.00333 0.01000
        16 0.04469 0.00625 46 0.00333 0.01000
        17 0.13880 0.01333 47 0.00333 0.01000
        18 0.13890 0.01333 48 0.00333 0.01000
        19 0.13890 0.01333 49 0.00333 0.01000
        20 0.13890 0.01333 50 0.00333 0.01000
        21 0.13890 0.01333 51 0.00333 0.01000
        22 0.13890 0.01333 52 0.00334 0.01000
        23 0.13890 0.01334 53 0.00334 0.01000
        24 0.13890 0.01334 54 0.00334 0.01000
        25 0.13890 0.01334 55 0.00334 0.01000
        26 0.00800 0.02300 56 0.00334 0.01000
        27 0.00800 0.02300 57 0.00334 0.01000
        28 0.00800 0.02300 58 0.00334 0.01000
        29 0.00800 0.02300 59 0.00334 0.01000
        下载: 导出CSV
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      出版历程
      • 收稿日期:2024-03-21
      • 修回日期:2024-04-24
      • 上网日期:2024-05-09
      • 刊出日期:2024-06-20

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