M. Sato et al., FORMATION OF CHEMICAL-SPECIES AND THEIR EFFECTS ON MICROORGANISMS USING A PULSED HIGH-VOLTAGE DISCHARGE IN WATER, IEEE transactions on industry applications, 32(1), 1996, pp. 106-112
The primary mechanism for sterilization of microorganisms by high-volt
age pulses has been considered to be an electrical breakdown of the ce
ll membrane. However, it is expected that many kinds of chemically act
ive species would be generated by an electrical discharge in a needle-
plate or rod-rod electrode system. Therefore it is necessary to identi
fy the chemical species produced by the discharge and to investigate l
ethal effects of the active species on microorganisms. Using a nozzle-
plate electrode configuration, the authors previously reported that ma
genta colored streamers propagated from the nozzle tip during a pulsed
discharge in water with various conductivities. The authors also inve
stigated the generation of ozone from oxygen bubbled through the disch
arge. In the present study, the formation of active species in water (
without O-2 flow) and their effects on yeast cells were investigated u
sing needle-plate electrodes. In the presence of the streamer discharg
e, H and OH radicals were detected hy means of emission spectroscopic
analysis of the discharge light. Hydrogen peroxide (H2O2) was also det
ected by absorption spectrophotometry using a reaction of peroxidase a
nd catalase. The effect of the electrical conductivity of the water on
the formation of the active species was investigated. Maximum . OH an
d H2O2 concentrations were obtained at a water conductivity of about 1
0(-5) S/cm. The H2O2 formation mechanism was considered to be a recomb
ination reaction of . OH. The lethal effects on beer yeast of . OH and
H2O2 generated by the pulsed electrical discharge in water were also
investigated. It was found that . OH had almost no effect in reducing
the survivors. However, the H2O2 did kill the yeast cells: the logarit
hm of the survival ratio decreased linearly with increasing H2O2 conce
ntration.