A plasma CVD device which comprises a substrate having a three-dimensional shape such as that of a bottle and which can form a coating on the surface of various substrates under atmospheric pressure, and a coating forming method are provided. This atmospheric pressure remote plasma CVD device is provided with a dielectric chamber which has a gas inlet, an inner space and a plasma outlet, and a plasma generation device which generates plasma in the inner space. The plasma outlet is provided with a nozzle that has an opening area smaller than the average cross-sectional area of the cross-sections perpendicular to the direction of gas flow in the inner space.

The present invention provides a plasma generating system that includes: a waveguide; a plasma cavity coupled to the waveguide and configured to generate a plasma therewithin by use of microwave energy; a hollow cylinder protruding from a wall of the waveguide and having a bottom cap that has an aperture; a detection unit for receiving the light emitted by the plasma through the aperture and configured to measure intensities of the light in an ultraviolet (UV) range and an infrared (IR) range; and a controller for controlling the detection unit.

A hybrid plasma source and an operation method thereof, the hybrid plasma source is formed by combining the mechanisms of microwave plasma and transformer coupled plasma for gas dissociation and chemical activation. A reaction chamber of the hybrid plasma source is composed of two microwave resonant chambers and sets of hollow metal tubes, after a high-intensity electric field is generated by the microwave resonant chambers to generate a plasma, a high power and high density plasma generated by the highly-efficient coupling mechanism of the transformer coupled plasma is capable of greatly improving a gas conductance, each set of the hollow metal tubes is driven by each set of ferrite transformer magnetic cores to disperse power, which reduces an energy density of each of the hollow metal tubes and reduces occurrence of plasma entering a contraction mode from a diffusion mode, thereby further improving an operable gas flow rate.

A plasma processing apparatus includes: a high voltage power supply for supplying a high voltage power to a magnetron; and a detector for detecting a microwave output from the magnetron, wherein based on a result of comparing a signal, which is obtained by adding an output from the detector to an AC component of a current detected from an output of the high voltage power supply, with a setting value of the output of the high voltage power supply, the output of the high voltage power supply is adjusted.

Sterilisation systems suitable for clinical use for generating a flow of hydroxyl radicals, comprising: a coaxial transmission line comprising an inner and outer conductor; an end cap mounted on a distal end of the coaxial transmission line, wherein the end cap comprises an outlet aperture; a fluid conduit extending from a fluid inlet to the outlet aperture; and a plasma generating region at a proximal end of the outlet aperture, wherein the plasma generating region contains a first electrode electrically connected to the inner conductor, and a second electrode electrically connected to the outer conductor, wherein the fluid conduit defines a fluid flow path through the device aligned with a feed direction in which fluid is receivable through the fluid inlet, and wherein the first electrode and second electrode oppose each other in a transverse direction across the longitudinal fluid flow path in the plasma generating region.

Systems and methods for plasma based synthesis of graphitic materials. The system includes a plasma forming zone configured to generate a plasma from radio-frequency radiation, an interface element configured to transmit the plasma from the plasma forming zone to a reaction zone, and the reaction zone configured to receive the plasma. The reaction zone is further configured to receive feedstock material comprising a carbon containing species, and convert the feedstock material to a product comprising the graphitic materials in presence of the plasma.

In a film-forming apparatus according to an aspect, a substrate placed on a substrate placing region passes through a first region and a second region in this order by rotation of a placing table. A precursor gas is supplied to the first region. Plasma of a reaction gas is generated in the second region by a plasma generation section. The plasma generation section includes an antenna that supplies microwaves as a plasma source. The antenna includes a dielectric window member and a waveguide. The window member is provided above the second region. The waveguide defines a waveguide path that extends in a radial direction. The waveguide is formed with a plurality of slot holes that allow the microwaves to pass therethrough from the waveguide path toward the window member plate. A bottom surface of the window member defines a groove that extends in the radial direction.

Provided herein are high energy ion beam generator systems and methods that provide low cost, high performance, robust, consistent, uniform, low gas consumption and high current/high-moderate voltage generation of neutrons and protons. Such systems and methods find use for the commercial-scale generation of neutrons and protons for a wide variety of research, medical, security, and industrial processes.

The present disclosure relates to a cold plasma generating apparatus that can efficiently ignite (initially discharge) cold plasma and easily match common impedance and that is optimized for use in applications related to sterilization because it can uniformly distribute power to multiple plasma sources through a single power supply in a multi-plasma array configuration and increase effective plasma volume, and a multi-cold plasma array apparatus comprising the same.

Methods and systems include supplying pulsed microwave radiation through a waveguide, where the microwave radiation propagates in a direction along the waveguide. A pressure within the waveguide is at least 0.1 atmosphere. A supply gas is provided at a first location along a length of the waveguide, a majority of the supply gas flowing in the direction of the microwave radiation propagation. A plasma is generated in the supply gas, and a process gas is added into the waveguide at a second location downstream from the first location. A majority of the process gas flows in the direction of the microwave propagation at a rate greater than 5 slm. An average energy of the plasma is controlled to convert the process gas into separated components, by controlling at least one of a pulsing frequency of the pulsed microwave radiation, and a duty cycle of the pulsed microwave radiation.