"71985" . "P\u0159edneseno:(ICPIG)/31./Granada,14.07.2013-19.07.2013 Effects of pulse repetition rate of input power on the properties and the chemical activity of pulsed high-voltage discharge in water generated using a magnetic pulse compression pulsed-power modulator were investigated. By varying the pulse repetition rate, two distinct modes of discharge plasma were formed in water. The first mode was characterized by the formation of corona-like discharge propagating through the water in form of streamer channels. The second mode occurred when the pulse repetition rate was increased to above a certain threshold value (typically above 500 Hz) and was characterized by the suppression of the formation of streamer channels in water. Instead, all plasma occurred inside a spheroidal aggregate of very fine gas bubbles which formed around the discharge electrode tip. This work investigates plasmachemical properties of underwater discharge produced under these conditions using phenol as the"@en . . "Effects of pulse frequency on plasmachemical activity of electrical discharge in water(ICPIG2013)" . . . . "Effects of pulse frequency on plasmachemical activity of electrical discharge in water(ICPIG2013)"@en . . "Luke\u0161, Petr" . "1"^^ . "plasma; phenol"@en . "Ruma, R." . "RIV/61389021:_____/13:00398743!RIV14-AV0-61389021" . . . "RIV/61389021:_____/13:00398743" . "Aoki, N." . . . . . "[901F6588EAEA]" . "Hosseini, S.H.R." . . "Effects of pulse frequency on plasmachemical activity of electrical discharge in water(ICPIG2013)" . "Effects of pulse frequency on plasmachemical activity of electrical discharge in water(ICPIG2013)"@en . "Sakugawa, T." . "I" . . . "6"^^ . "Akiyama, H." . "P\u0159edneseno:(ICPIG)/31./Granada,14.07.2013-19.07.2013 Effects of pulse repetition rate of input power on the properties and the chemical activity of pulsed high-voltage discharge in water generated using a magnetic pulse compression pulsed-power modulator were investigated. By varying the pulse repetition rate, two distinct modes of discharge plasma were formed in water. The first mode was characterized by the formation of corona-like discharge propagating through the water in form of streamer channels. The second mode occurred when the pulse repetition rate was increased to above a certain threshold value (typically above 500 Hz) and was characterized by the suppression of the formation of streamer channels in water. Instead, all plasma occurred inside a spheroidal aggregate of very fine gas bubbles which formed around the discharge electrode tip. This work investigates plasmachemical properties of underwater discharge produced under these conditions using phenol as the" .