40 research outputs found
Amorphous carbon film deposition on inner surface of tubes using atmospheric pressure pulsed filamentary plasma source
Uniform amorphous carbon film is deposited on the inner surface of quartz
tube having the inner diameter of 6 mm and the outer diameter of 8 mm. A pulsed
filamentary plasma source is used for the deposition. Long plasma filaments (~
140 mm) as a positive discharge are generated inside the tube in argon with
methane admixture. FTIR-ATR, XRD, SEM, LSM and XPS analyses give the conclusion
that deposited film is amorphous composed of non-hydrogenated sp2 carbon and
hydrogenated sp3 carbon. Plasma is characterized using optical emission
spectroscopy, voltage-current measurement, microphotography and numerical
simulation. On the basis of observed plasma parameters, the kinetics of the
film deposition process is discussed
Separation of VUV/UV photons and reactive particles in the effluent of a He/O2 atmospheric pressure plasma jet
Cold atmospheric pressure plasmas can be used for treatment of living tissues
or for inactivation of bacteria or biological macromolecules. The treatment is
usually characterized by a combined effect of UV and VUV radiation, reactive
species, and ions. This combination is usually beneficial for the effectiveness
of the treatment but it makes the study of fundamental interaction mechanisms
very difficult. Here we report on an effective separation of VUV/UV photons and
heavy reactive species in the effluent of a micro scale atmospheric pressure
plasma jet (-APPJ). The separation is realized by an additional flow of
helium gas under well-defined flow conditions, which deflects heavy particles
in the effluent without affecting the VUV and UV photons. Both components of
the effluent, the photons and the reactive species, can be used separately or
in combination for sample treatment. The results of treatment of a model plasma
polymer film and vegetative Bacillus subtilis and Escherichia coli cells are
shown and discussed. A simple model of the He gas flow and reaction kinetics of
oxygen atoms in the gas phase and at the surface is used to provide a better
understanding of the processes in the plasma effluent. The new jet
modification, called X-Jet for its appearance, will simplify the investigation
of interaction mechanisms of atmospheric pressure plasmas with biological
samples.Comment: 10 pages, 7 figures, submitted to Journal of Physics D: Applied
Physic
Spectroscopic characterization of atmospheric pressure um-jet plasma source
A radio frequency um-jet plasma source is studied using He/O2 mixture. This
um-jet can be used for different applications as a source of chemical active
species e.g. oxygen atoms, molecular metastables and ozone. Using
absolutely-calibrated optical emission spectroscopy and numerical simulation,
the gas temperature in active plasma region and plasma parameters (electron
density and electron distribution function) are determined. Concentrations of
oxygen atoms and ozone in the plasma channel and in the effluent of the plasma
source are measured using emission and absorption spectroscopy. To interpret
the measured spatial distributions, the steady-state species' concentrations
are calculated using determined plasma parameters and gas temperature. At that
the influence of the surface processes and gas flow regime on the loss of the
active species in the plasma source are discussed. The measured spatial
distributions of oxygen atom and ozone densities are compared with the
simulated ones.Comment: 29 pages, 10 figure
Production of XeO * in a CW microwave discharge
A low-power CW microwave discharge at 2.45 GHz was used to produce XeO * excimer molecules. It was found that a total gas pressure between 5 and 20 Torr, absorbed power of about 20–100 W, and an oxygen-to-xenon ratio of 1∶100 maximized the XeO( 1 S− 1 D) green emission at 5200 to 5600 Å. The XeO * emission appeared in the cooler parts of the discharge near the containment tube walls and in the electric field nodes of the TM 012 resonant mode.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/45480/1/11090_2005_Article_BF01023916.pd
Experimental and computational investigations of electron dynamics in micro atmospheric pressure radio-frequency plasma jets operated in He/N2 mixtures
The electron power absorption dynamics in radio frequency driven micro atmospheric pressure capacitive plasma jets are studied based on experimental phase resolved optical emission spectroscopy and the computational particle in cell simulations with Monte Carlo treatment of collisions. The jet is operated at 13.56 MHz in He with different admixture concentrations of N2 and at several driving voltage amplitudes. We find the spatio-temporal dynamics of the light emission of the plasma at various wavelengths to be markedly different. This is understood by revealing the population dynamics of the upper levels of selected emission lines/bands based on comparisons between experimental and simulation results. The populations of these excited states are sensitive to different parts of the electron energy distribution function and to contributions from other excited states. Mode transitions of the electron power absorption dynamics from the Ω- to the Penning-mode are found to be induced by changing the N2 admixture concentration and the driving voltage amplitude. Our numerical simulations reveal details of this mode transition and provide novel insights into the operation details of the Penning-mode. The characteristic excitation/emission maximum at the time of maximum sheath voltage at each electrode is found to be based on two mechanisms: (i) a direct channel, i.e. excitation/emission caused by electrons generated by Penning ionization inside the sheaths and (ii) an indirect channel, i.e. secondary electrons emitted from the electrode due to the impact of positive ions generated by Penning ionization at the electrodes