A plasma application apparatus including: an application instrument which has a plasma generation unit, and is configured to discharge at least one of plasma generated by the plasma generation unit and a reactive gas generated by the plasma; and a supply unit for supplying electric power and a plasma generating gas to the application instrument, a supporting part extending upward from the supply unit, a power/gas supply line connecting the application instrument to the supply unit, and a connecting part connecting at least one of the application instrument and the power/gas supply line to the supporting part,

Applications of dielectric barrier discharge (DBD) based atmospheric pressure plasma jets are often limited by the relatively small area of treatment due to their 1D configuration. This system generates 2D plasma jets permitting fast treatment of larger targets. DBD evolution starts with formation of transient anode glow, and continues with development of cathode-directed streamers. The anode glow can propagate as an ionization wave along the dielectric surface through and outside of the discharge gap. Plasma propagation is not limited to 1D geometry such as tubes, and can be organized in a form of a rectangular plasma jet, or other 2D or 3D shapes. Also described are a method for generating 2D plasma jets and use of the 2D plasma jets for cancer therapy.

A dielectric barrier discharge reactor for catalytic nonthermal plasma production of hydrogen from methane. The dielectric barrier discharge reactor includes two end pieces connected by a dielectric tube, two steam generators, two catalyst cages, two perforated tube center electrodes, a center electrode rod, a grounding electrode. In one aspect, the end pieces and the dielectric tube are fabricated from ceramic and fused quartz respectively. In another aspect, the dielectric barrier discharge reactor further includes catalyst cages. In yet another aspect, the catalyst cages contain catalysts in form of pellets. In an alternate aspect, the dielectric barrier discharge reactor acts to cause a reaction between incoming reactant gases. The reaction is achieved under a plasma which is generated between the perforated tubular center electrode and the ground electrode. In yet another alternate aspect, the dielectric barrier discharge reactor is used at home to generate hydrogen from methane.

A system, device and method are provided for exposing a patient to therapeutic resonant frequency patterns (RFP) for therapy and treatment of a patient, for example, biological tissue such as muscle, tendon, ligament, and nerve tissue. The resonance frequencies originate from many bioactive substances, pharmaceuticals or other compounds, and key frequencies of the RFP of a compound can be replicated and then delivered to a patient using an electromagnetic catalyst to provide therapeutic benefits. RFPs can be imprinted in a separate device using a plasma imprinting device and method. This separate device can be actively excited by a delivery mechanism that uses electromagnetic or mechanical waves to interact with the device. The actively excited device transmits the RFPs or therapeutic resonant frequency patterns to the patient for similar enhancements and therapeutic benefits.

A system and methods for sterilizing and drying contaminated articles, particularly medical articles, and more particularly the hollow internal areas of medical instruments or lumens of medical endoscopes. The system includes a plasma generator having an electrode, a shield, and a dielectric gap between the electrode and the shield. A source of electrical power connected to the plasma generator applies an electrode energy density between the electrode and the shield. A source of a sterilizing gas precursor provides a flow of the sterilizing gas precursor through the plasma generator to generate a plasma, thereby forming a sterilizing gas including acidic and/or oxidizing species. The contaminated article is exposed to the sterilizing gas for a time sufficient to achieve a desired degree of sterilization. A turbulent flow of a drying gas is used to dry the contaminated article alternately with the exposure of the contaminated article to the sterilizing gas.

A gas passing groove, a high-voltage electrode groove, and a ground electrode groove provided to an electrode unit base are each helical in plan view. An electrode unit lid is placed on a front surface of the electrode unit base so that a high-voltage conduction hole and a high-voltage conduction point coincide with each other in plan view. An electrode cooling plate is placed on a front surface of the electrode unit lid so that a high-voltage opening includes the high-voltage conduction hole as a whole in plan view. The electrode unit lid and the electrode cooling plate are placed on the front surface of the electrode unit base so that a ground conduction groove, a ground conduction hole, and a ground conduction point coincide with one another in plan view.

A dielectric barrier discharge ionization detector capable of achieving a high signal-to-noise ratio is provided. The detector includes: a discharging section for generating plasma from argon-containing gas by electric discharge; and a charge-collecting section for ionizing a component in a sample gas by an effect of the plasma and for detecting ion current formed by the ionized component. The discharging section includes a cylindrical dielectric tube having a high-voltage electrode connected to AC power source as well as upstream-side and downstream-side ground electrodes and formed on its outer circumferential wall. A semiconductor film is formed on the inner circumferential surface of the tube. The upstream-side and downstream-side ground electrodes are respectively made longer than the initiation distances for a creeping discharge between the high-voltage electrode and a tube-line tip member as well as between the high-voltage electrode and the charge-collecting section.

A plasma generating apparatus includes a dielectric medium with electrodes on first and second sides of the dielectric medium. A power source creates a voltage differential between the electrodes on the first side and the electrodes on the second side of the dielectric medium. Plasma is generated on both of the first and second sides of the dielectric medium as a result of the voltage differential.

A pathogen and pest exterminating device that can efficiently exterminate pathogens and pests in a shorter time. One electrode includes a part to be inserted into a reaction vessel, and other electrode is arranged in a position that opposes the insertion part. A water supply unit is provided to supply water to the reaction vessel through the insertion part, and a gas supply unit provided of supplying gas, which will become plasma, to the reaction vessel. A power supply unit is provided to be capable of applying voltage between the insertion part and the other electrode such that OH radicals are generated inside the reaction vessel to which the water and the gas are supplied. The insertion part is formed in a shape that restricts, between itself and the other electrode, a flow rate of water from the water supply unit such as a coil, waveform, or mesh shape.

Provided is a plasma generation apparatus including: a housing in which a window is defined at one side in a first direction; a stick type plasma source provided in the housing to generate plasma toward the window; and a driving unit coupled to the plasma source to allow one end of the plasma source to perform a reciprocating movement in a second direction that is a longitudinal direction of the window.