Xu Weiqun, Lü Weitao, Qi Qi, et al. Luminosity and current characteristics of metal-vaporized channel of an artificially triggered lightning. J Appl Meteor Sci, 2023, 34(6): 739-748. DOI:  10.11898/1001-7313.20230609.
Citation: Xu Weiqun, Lü Weitao, Qi Qi, et al. Luminosity and current characteristics of metal-vaporized channel of an artificially triggered lightning. J Appl Meteor Sci, 2023, 34(6): 739-748. DOI:  10.11898/1001-7313.20230609.

Luminosity and Current Characteristics of Metal-vaporized Channel of an Artificially Triggered Lightning

DOI: 10.11898/1001-7313.20230609
  • Received Date: 2023-06-14
  • Rev Recd Date: 2023-09-17
  • Publish Date: 2023-11-27
  • Channel current is an important parameter of the lightning discharge, but it's difficult to be directly measured due to the randomness and instantaneity of the natural lightning. The channel luminosity, however, is relatively easier to obtain. If there is a definite relationship between channel current and luminosity, the channel current can be estimated based on its luminosity. The correlation between the current and luminosity of lightning channel can be obtained through artificially triggered lightning experiments, during which the channel current can be directly measured and close-range optical observations of the lightning channel can be carried out.Base on observations of an artificially triggered lightning obtained at the Field Experiment Base on Lightning Sciences, China Meteorological Administration (CMA_FEBLS) in 2022, characteristic parameters of the channel-base current, the luminosity of the metal-vaporized channel, and their correlation are analyzed. The spatial movement of the metal-vaporized channel during the multiple return stroke processes is distinguished using still image with high spatial resolution. Combined with the high-speed video camera images and the channel current data, the correlation between the luminosity of the metal-vaporized channel and the channel current in the process of return strokes, and M components are studied. The results show that compared with the peak current, its squared value has stronger correlation with the peak luminosity for 13 return strokes. For the return stroke followed by a long continuing current, as well as the return stroke decay stage, both the current and M components superimposed on it show good linear correlations with the channel luminosity, with correlation coefficients of 0.981 and 0.988, respectively. However, the slope values of correlation fitting lines for the channel current versus the channel luminosity of the return stroke decay stage and the subsequent continuing current are obviously different. For M components superimposed on the long continuing current, a time delay for the peak luminosity relative to the peak current is revealed, and it is found that a smaller pulse peak current corresponds to a larger delay time.
  • Fig. 1  Schematic diagram of the location of lightning rod and optical observation site

    Fig. 2  Horizontal distribution of flash T2211 metal-vaporized channel gray values at 220 m height

    Fig. 3  Relative integrated luminosity(a) and current(b) of the first return stroke of flash T2211

    Fig. 4  Simultaneously measured luminosity and current of flash T2211 (a)relative integrated luminosity, (b)small-range measured current, (c)large-range measured current

    Fig. 5  Still image of the metal-vaporized channel of flash T2211 (the exposure time is 1 s)

    Fig. 6  Luminosity and current variation during decay phase for return stroke R1(a) and return stroke R3(b)

    Fig. 7  Scatter plots of peak current(a) and square of peak current(b) versus peak relative integrated luminosity for return strokes

    Fig. 8  Luminosity and current variation for return stroke R13 and its continuing current(a) with scatter plot(b)

    Fig. 9  Scatter plots of peak current versus peak luminosity(a) and delay time of peak luminosity(b) for M components superimposed on R13-CC

  • [1]
    Gomes C,Cooray V.Correlation between the optical signatures and current wave forms of long sparks:Applications in lightning research.J Electrostat,1998,43(4):267-274. doi:  10.1016/S0304-3886(98)00008-4
    [2]
    Amarasinghe D, Sonnadara U, Berg M, et al. Correlation between brightness and channel currents of electrical discharges. IEEE Trans Dielectr Electr Insul, 2007, 14(5): 1154-1160. doi:  10.1109/TDEI.2007.4339475
    [3]
    Diendorfer G, Mair M, Schulz W. Detailed Brightness Versus Lightning Current Amplitude Correlation of Flashes to the Gaisberg Tower. 26th International Conference on Lightning Protection, Cracow, Poland, 2002.
    [4]
    Zhang Y J, Yang S J, Lü W T, et al. Comprehensive observation experiments and application study of artificially triggered lightning during 2006-2011. J Appl Meteor Sci, 2012, 23(5): 513-522. http://qikan.camscma.cn/article/id/20120501
    [5]
    Ma R Y, Zheng D, Yao W, et al. Thunderstorm feature dataset and characteristics of thunderstorm activities in China. J Appl Meteor Sci, 2021, 32(3): 358-369. doi:  10.11898/1001-7313.20210308
    [6]
    Yan L C, Zhang W J, Zhang Y J, et al. Temporal and spatial distribution of thunderstorms and strong winds with characteristics of lightning and convective activities in the South China Sea. J Appl Meteor Sci, 2023, 34(4): 503-512. doi:  10.11898/1001-7313.20230410
    [7]
    Wu X T, Wang X Y, Zheng D, et al. Effects of different aerosols on cloud-to-ground lightning activity in the Yangtze River Delta. J Appl Meteor Sci, 2023, 34(5): 608-618. doi:  10.11898/1001-7313.20230509
    [8]
    Guan Y N, Lü W T, Qi Q, et al. Difference between 2D and 3D development characteristics of an upward lightning leader. J Appl Meteor Sci, 2023, 34(5): 598-607. doi:  10.11898/1001-7313.20230508
    [9]
    Zhang Y J, Lv W T, Chen S D, et al. A review of lightning observation experiments during the last ten years in Guangdong. Acta Meteor Sinica, 2016, 74(5): 655-671. https://www.cnki.com.cn/Article/CJFDTOTAL-QXXB201605001.htm
    [10]
    Xiao T, Zhang Y, Lü W T, et al. Current and electromagnetic field of M component in triggered lightning. J Appl Meteor Sci, 2013, 24(4): 446-454. http://qikan.camscma.cn/article/id/20130407
    [11]
    Qian Y, Zhang Y, Zhang Y J, et al. Characteristics and simulation of artificially triggered lightning precursor current pulse. J Appl Meteor Sci, 2016, 27(6): 716-724. doi:  10.11898/1001-7313.20160608
    [12]
    Wang J X, Zhang Y, Chen Z F, et al. Relationship between current characteristics of rocket-triggered lightning during different discharge stages. J Appl Meteor Sci, 2020, 31(2): 224-235. doi:  10.11898/1001-7313.20200209
    [13]
    Fan Y F, Lu G P, Zhang Y, et al. Characteristics of medium-low frequency magnetic fields of initial continuous current in rocket-triggered lightning. J Appl Meteor Sci, 2020, 31(2): 213-223. doi:  10.11898/1001-7313.20200208
    [14]
    Zhang Y, Chen Z F, Wang J X, et al. Observation of the whole discharge process during a multi-stroke triggered lightning by continuous interferometer. J Appl Meteor Sci, 2020, 31(2): 197-212. doi:  10.11898/1001-7313.20200207
    [15]
    Zhang Y, Lü W T, Chen L W, et al. Evaluation of GHMLLS performance characteristics based on observations of artificially triggered lightning. J Appl Meteor Sci, 2022, 33(3): 329-340. doi:  10.11898/1001-7313.20220307
    [16]
    Idone V P, Orville R E. Correlated peak relative light intensity and peak current in triggered lightning subsequent return strokes. J Geophys Res Atmos, 1985, 90(D4): 6159-6164.
    [17]
    Wang D, Takagi N, Watanabe T, et al. A comparison of channel-base currents and optical signals for rocket-triggered lightning strokes. Atmos Res, 2005, 76(1/2/3/4): 412-422.
    [18]
    Zhou M, Wang D, Wang J, et al. Correlation between the channel-bottom light intensity and channel-base current of a rocket-triggered lightning flash. J Geophys Res Atmos, 2014, 119(23): 13457-13473.
    [19]
    Carvalho F L, Uman M A, Jordan D M, et al. Lightning current and luminosity at and above channel bottom for return strokes and M-components. J Geophys Res Atmos, 2015, 120(20): 10645-10663.
    [20]
    Wang C W, Liu X S, Dong W S, et al. The characteristics of the channel luminosity of triggered lightning flashes. Plateau Meteor, 1998, 17(1): 10-23. https://www.cnki.com.cn/Article/CJFDTOTAL-GYQX801.001.htm
    [21]
    Lu W T, Zhang Y J, Zhou X J, et al. Analysis of channel luminosity characteristics in rocket-triggered lightning. Acta Meteor Sinica, 2007, 65(6): 983-993. https://www.cnki.com.cn/Article/CJFDTOTAL-QXXB200706015.htm
    [22]
    Zhang H M, Zhang Y J, Lyu W T, et al. Analysis of the spectral characteristics of triggered lightning. Adv Atmos Sci, 2019, 36(11): 1265-1272.
    [23]
    Walker T D, Christian H J. Triggered lightning spectroscopy: Part 1. A qualitative analysis. J Geophys Res Atmos, 2017, 122(15): 8000-8011.
    [24]
    Pilkey J T, Uman M A, Hill J D, et al. Rocket-and-wire triggered lightning in 2012 tropical storm Debby in the absence of natural lightning. J Geophys Res Atmos, 2013, 118(23): 13158-13174.
    [25]
    Zhang H M, Zhang Y J, Lü W T, et al. The spectra structure characteristic of triggered lightning channel. Spectrosc Spectr Anal, 2017, 37(6): 1692-1695. https://www.cnki.com.cn/Article/CJFDTOTAL-GUAN201706007.htm
    [26]
    Zhou E W, Lu W T, Zhang Y, et al. Correlation analysis between the channel current and luminosity of initial continuous and continuing current processes in an artificially triggered lightning flash. Atmos Res, 2013, 129/130: 79-89.
    [27]
    Wang D, Rakov V A, Uman M A, et al. Characterization of the initial stage of negative rocket-triggered lightning. J Geophys Res Atmos, 1999, 104(D4): 4213-4222.
    [28]
    Dayeh M A, Evans N D, Fuselier S A, et al. First images of thunder: Acoustic imaging of triggered lightning. Geophys Res Lett, 2015, 42(14): 6051-6057.
    [29]
    Quick M G, Krider E P. Optical power and energy radiated by natural lightning. J Geophys Res Atmos, 2013, 118(4): 1868-1879.
    [30]
    Liang C, Carlson B, Lehtinen N, et al. Differing current and optical return stroke speeds in lightning. Geophys Res Lett, 2014, 41(7): 2561-2567.
    [31]
    Uman M A. Determination of lightning temperature. J Geophys Res, 1969, 74(4): 949-957.
    [32]
    Walker T D, Christian H J. Triggered lightning spectroscopy: 2. A quantitative analysis. J Geophys Res Atmos, 2019, 124(7): 3930-3942.
    [33]
    da Silva C L, Sonnenfeld R G, Edens H E, et al. The plasma nature of lightning channels and the resulting nonlinear resistance. J Geophys Res Atmos, 2019, 124(16): 9442-9463.
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    • Received : 2023-06-14
    • Accepted : 2023-09-17
    • Published : 2023-11-27

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