Sterilization of materials using a one atmosphere uniform glow discharge plasma

Ku, Yongmin; Brickman, C.; Wintenberg, K.-K.; Montie, Thomas C.; Tsai, Ping-Huei; Wadsworth, Larry C.; Roth, J. Reece

doi:10.1109/plasma.1996.550731

Cited by 5 publications

(1 citation statement)

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“…On the other hand, non-vacuum plasma operation may enable a variety of processes at lower cost, allow new processes for work pieces that are not vacuum compatible and extend existing plasma methods to sealed gas systems that operate in mixtures of precursor gases at atmospheric pressure. In particular, glow discharges at atmospheric pressure are of interest for surface modification [2][3][4][5], thin film deposition [6,7], surface cleaning [8], biomaterial decontamination [9] and sterilization [5,[10][11][12][13][14][15][16][17][18] as well as automotive [19,20] applications. The efficacy of plasmas in this broad range of applications is largely due to their capability of producing large amounts of chemically reactive species, molecular fragments and energetic visible/UV/VUV photons.…”

Section: Introductionmentioning

confidence: 99%

Optical and RF electrical characteristics of atmospheric pressure open-air hollow slot microplasmas and application to bacterial inactivation

Rahul¹,

Stan²,

Rahman³

et al. 2005

J. Phys. D: Appl. Phys.

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We report electrical properties of radio frequency (RF)-driven hollow slot microplasmas operating in open air but with uniform luminous discharges at RF current densities of the order of A cm −2 . We employ interelectrode separations of 100-600 µm to achieve this open-air operation but because the linear slot dimension of our electrode designs are of extended length, we can achieve, for example, open-air slot shaped plasmas 30 cm in length. This creates a linear plasma source for wide area plasma driven surface treatment applications. RF voltages at frequencies of 4-60 MHz are applied to an interior electrode to both ignite and sustain the plasma between electrodes. The outer slotted electrode is grounded. Illustrative absolute emission of optical spectra from this source is presented in the region from 100 to 400 nm as well as total oxygen radical fluxes from the source. We present both RF breakdown and sustaining voltage measurements as well as impedance values measured for the microplasmas, which use flowing rare gas in the interelectrode region exiting into open air. The requirement for rare gas flow is necessary to get uniform plasmas of dimensions over 30 cm, but is a practical disadvantage. In one mode of operation we create an out-flowing afterglow plasma plume, which extends 1-3 mm from the grounded open slot allowing for treatment of work pieces placed millimetres away from the grounded electrode. This afterglow configuration also allows for lower gas temperatures impinging on substrates, than the use of active plasmas. Work pieces are not required to be part of any electrical circuit, bringing additional practical advantages. We present a crude lumped parameter equivalent circuit model to analyse the effects of changing RF sheaths with frequency of excitation and applied RF current to better understand the relative roles of sheath and bulk plasma behaviour observed in electrical characteristics. Estimates of the bulk plasma densities are also provided. Finally, we present results of afterglow plasma based bacteria inactivation studies (Escherichia coli, Bacillus atrophaeus and B. atrophaeus spores) in which we employ the flowing afterglow plume from a hollow slot microplasma device rather than the active plasma itself, which is fully contained between electrodes.

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