Vacuum arc plasma emission spectroscopy diagnosis

Jin Zhang; Zhao Yuan; Lixue Chen; Shan Liu

doi:10.11884/HPLPB202133.210116

[1] Wang Zhangqi, Zou Jiyan, He Junjia et al. Power switch technology[M]. Wuhan: Huazhong University of Science & Technology Press, 2003.

[4] Khakpour A, Franke S, Methling R, et al. Optical and electrical investigation of transition from anode spot type 1 to anode spot type 2[J]. IEEE Transactions on Plasma Science, 45, 2126-2134(2017).

[5] Methling R, Gorchakov S, Lisnyak M V, et al. Spectroscopic investigation of a Cu—Cr vacuum arc[J]. IEEE Transactions on Plasma Science, 43, 2303-2309(2015).

[6] Lisnyak M, Pipa A V, Gorchakov S, et al. Overview spectra and axial distribution of spectral line intensities in a high-current vacuum arc with CuCr electrodes[J]. Journal of Applied Physics, 188, 123304(2015).

[7] Khakpour A, Methling R, Franke S, et al. Vapor density and electron density determination during high-current anode phenomena in vacuum arcs[J]. Journal of Applied Physics, 124, 243301(2018).

[10] Wang Haoran, Wang Zhenxing, Liu Jiankun, et al. Optical absorption spectroscopy of metallic (Cr) vapor in a vacuum arc[J]. Journal of Physics D: Applied Physics, 51, 035203(2017).

[11] Gtschakow S, Popov S, Khakpour A, et al. Cu Cr density determination during highcurrent disge modes in vacuum arcs[C]2018 28th International Symposium on Disges Electrical Insulation in Vacuum (ISDEIV). Greifswald: IEEE, 2018: 181184.

[12] Khakpour A, Popov S, Franke S, et al. Determination of Cr density after current zero in a high-current vacuum arc considering anode plume[J]. IEEE Transactions on Plasma Science, 45, 2108-2114(2017).

[13] Wang Zhenxing, Liu Jiankun, Li Yuecheng, et al. Two-dimensional observation of copper atoms after forced extinction of vacuum arcs by laser-induced fluorescence[J]. IEEE Transactions on Plasma Science, 48, 2777-2789(2020).

[14] Liu Jiankun, Li Yi, Geng Yingsan, et al. Two dimensional distribution of metallic (Cu) vap in a fced vacuum arc extinction by LIF[C]2018 28th International Symposium on Disges Electrical Insulation in Vacuum (ISDEIV). Greifswald: IEEE, 2018: 403406.

[15] Liu Jiankun, Zha Ziru, Wang Zhenxing, et al. Two dimensional distribution diagnostic of copper vap in a vacuum arc by laserinduced fluescence[C]2019 5th International Conference on Electric Power EquipmentSwitching Technology (ICEPEST). Kitakyushu: IEEE, 2019: 144147.

[16] Lins G. Measurement of the neutral copper vapor density around current zero of a 500-A vacuum arc using laser-induced fluorescence[J]. IEEE Transactions on Plasma Science, 13, 577-581(1985).

[17] Wang Haan, Liu Ziyuan, Liu Jiankun, et al. Investigation of vacuum arc extinction process by planar laserinduced fluescence[C]2018 28th International Symposium on Disges Electrical Insulation in Vacuum (ISDEIV). Greifswald: IEEE, 2018: 313316.

[18] Lins G. Collisional transfer and neutral copper vapour density during a diffuse vacuum arc[J]. Journal of Physics D: Applied Physics, 23, 784(1990).

[20] Griem H R. Plasma spectroscopy[M]. New Yk: McGrawHill, 1964.

[21] Chen Xinkun. Principles of atomic emission spectroscopy[M] Tianjin: Tianjin Science Technology Press, 1991).

[22] Khakpour A, Franke S, Gortschakow S, et al. Investigation of anode plume in vacuum arcs using different optical diagnostic methods[J]. IEEE Transactions on Plasma Science, 47, 3488-3495(2019).

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