9 Macheret S O, Shneider M N, Murray R C. Ionization in strong electric fields and dynamics of nanosecond-pulse plasmas. Phys Plasmas, 2006, 13: 023502
[6]
10 Pai D Z, Lacoste D A, Laux C O. Transitions between corona, glow, and spark regimes of nanosecond repetitively pulsed discharge in air at atmospheric air. J Appl Phys, 2010, 107: 093303
[7]
12 Shao T, Zhang C, Niu Z, et al. Runaway electron preionized diffuse discharges in atmospheric pressure air with a point-to-plane gap in repetitive pulsed mode. J Appl Phys, 2011, 109: 083306
[8]
17 Yang D, Wang W, Jia L, et al. Production of atmospheric pressure diffuse nanosecond pulsed dielectric barrier discharge using the array needles-plate electrode in air. J Appl Phys, 2011, 109: 073308
[9]
18 Liu Z, Wang W, Yang D, et al. A large-area diffuse air discharge plasma excited by nanosecond pulse under a double hexagon needle-array electrode. Spectrochim Acta Part A-Molecul Biomol Spectr, 2014, 121: 698-703
[10]
19 Li L, Liu Y, Ge Y, et al. Generating diffuse discharge via repetitive nanosecond pulses and line-line electrodes in atmospheric air. Rev Scient Instr, 2013, 84: 105105
[11]
23 Zhang C, Shao T, Niu Z, et al. Pulse repetition frequency effect on nanosecond-pulse diffuse discharge in atmospheric-pressure air with a point-to-plane gap. IEEE Trans Plasma Sci, 2011, 39: 2070-2071
25 Levatter J I, Lin S C. Necessary conditions for the homogenous formation of pulsed avalanche discharges at high gas pressure. J Appl Phys, 1980, 81: 210-222
6 Shao T, Zhang C, Niu Z, et al. Diffuse discharge, runaway electron, and X-ray in an atmospheric pressure air in an inhomogeneous electrical field in repetitive pulsed modes. Appl Phys Lett, 2011, 98: 021513
8 Ono R, Oda T. Formation and structure of primary and secondary streamers in positive pulsed corona discharge-Effect of oxygen concentration and applied voltage. J Phys D-Appl Phys, 2003, 36: 1952-1958
[18]
11 Tarasenko V F, Baksht E K, Shut'ko Y V. Diffuse discharges in atmospheric pressure air in repetitive pulsed mode with point-to-plane and point-to-point gaps. IEEE Trans Plasma Sci, 2011, 39: 2096-2097
[19]
13 Shao T, Tarasenko V F, Zhang C, et al. Generation of runaway electrons and X-rays in repetitive nanosecond pulse corona discharge in atmospheric pressure air. Appl Phys Express, 2011, 4: 066001
[20]
14 Zhang C, Shao T, Niu Z, et al. Diffuse and filamentary discharges in open air driven by repetitive high-voltage nanosecond pulses. IEEE Trans Plasma Sci, 2011, 39: 2208-2209
[21]
15 Shao T, Tarasenko V F, Zhang C, et al. Diffuse discharge produced by repetitive nanosecond pulses in open air, nitrogen, and helium. J Appl Phys, 2013, 113: 093301
20 Packan D. Repetitive nanosecond glow discharge in atmospheric pressure air. Doctoral Dissertation. Palo Alto, California, USA: Stanford University, 2003
[24]
21 Zhang C, Shao T, Ma H, et al. Experimental study on conduction current of positive nanosecond-pulse diffuse discharge at atmospheric pressure. IEEE Trans Dielectr Electr Insul, 2013, 20: 1304-1314
[25]
22 Shao T, Tarasenko V F, Zhang C, et al. Runaway electrons and X-rays from a corona discharge in atmospheric pressure air. New J Phys, 2011, 13: 113035
[26]
26 Pai D Z, Stancu G D, Lacoste D A, et al. Nanosecond repetitively pulsed discharges in air at atmospheric pressure-The spark regime. Plasma Sources Sci Technol, 2010, 19: 065015
[27]
27 Tarasenko V F, Baksht E K, Lomaev M I, et al. Transition of a diffuse discharge to a spark at nanosecond breakdown of high-pressure nitrogen and air in a nonuniform electric field. Tech Phys, 2013, 58: 1115-1121
[28]
28 Kutsyk I M, Babich L P, Donskoi, et al. Analysis of the results of a laboratory experiment on the observation of a runaway electron avalanche in air under high overvoltages. Plasma Phys Rep, 2012, 38: 891-898
[29]
29 Zhang C, Shao T, Tarasenko V F, et al. X-ray emission from a nanosecond-pulse discharge in an inhomogeneous electric field at atmospheric pressure. Phys Plasmas, 2012, 19: 123516
[30]
30 Zhang C, Shao T, Yan P, et al. Generation of X-ray emission in repetitive nanosecond-pulse discharge at atmospheric pressure. High Voltage Eng, 2013, 39: 2095-2104
[31]
31 Zhang C, Tarasenko V F, Shao T, et al. Effect of cathode materials on the generation of runaway electron beams and X-rays in atmospheric pressure air. Laser Part Beams, 2013, 31: 353-364
