A production apparatus for fine particles includes a vacuum chamber, a material feeding device connected to the vacuum chamber and feeding material particles from a material feeding port into the vacuum chamber, electrodes arranged in the vacuum chamber for generating plasma and a fine particle collection device connected to the vacuum chamber and collecting fine particles. The fine particles are produced from the material by generating electric discharge inside the vacuum chamber. The apparatus includes an inner chamber which forms an outside space with respect to the vacuum chamber installed between a wall of the vacuum chamber and a plasma generation region and gas supply pipes which supply a gas to the outside space between the wall of the vacuum chamber and a wall of the inner chamber.

A virtual cathode deposition apparatus utilises virtual plasma cathode for generation of high density electron beam to ablate a solid target. A high voltage electrical pulse ionizes gas to produce a plasma which temporarily appears in front of the target and serves as the virtual plasma cathode at the vicinity of target. This plasma then disappears allowing the ablated target material in a form of a plasma plume to propagate toward the substrate. Several virtual cathodes operating in parallel provide plumes that merge into a uniform plasma which when condensing on a nearby substrate leads to wide area deposition of a uniform thickness thin film.

An atmospheric pressure pulsed arc plasma source and method of using including a housing having a housing opening therein; an insulator tube having an insulator tube opening therein, retained within the housing opening; and a conductive tube, retained within the insulator tube opening. A nozzle is retained by the housing. A feed path is defined in the conductive tube and the nozzle and a gas feed port is operatively coupled to the feed path. Feedstock is provided in the feed path and electrically coupled to the conductive tube. A pulsed DC power source provides a pulsed voltage to the conductive tube. The plasma source emits a discharge stream having a temperature that is less than 50° C. from the nozzle and a coating is formed on a substrate.

A plasma generating apparatus may include a cathode assembly including a cathode, an anode assembly including an anode having therein a plasma generation space, and one or more magnetic force generators configured to generate a magnetic force. The anode assembly has one end portion in which a gas supply path is provided and the other end portion having an opening, the gas supply path configured to supply a plasma generating gas to the plasma generation space. The gas supply path is configured to generate a vortex of the plasma generating gas in the plasma generation space and said one or more magnetic force generators are arranged such that the magnetic force is generated in a direction opposite to a rotational direction of the vortex of the plasma generating gas.

A cathodic arc evaporation apparatus including a target which has a target surface including an active surface from where material can be evaporated in a cathodic arc process; a confinement surrounding an outer boarder of the target surface; an anode having an electron receiving surface, the anode encompassing at least one of the target and the confinement in at least one of a target plane and an axial distance in front of the active surface; and a magnetic guidance system adapted to provide a magnetic field at the target surface being essentially in parallel to at least an outer region of the target surface so that magnetic field lines are in parallel to the target surface or inclined to it in an acute angle α, whereat an active surface is defined in a surface area where magnetic field lines enter the target surface in an acute angle α≤45°.

A filter apparatus for arc ion evaporator used in the cathodic arc plasma deposition system according to this invention is characterized by a set of multiple straight tubes placing in parallel to one another wherein the size and/or amount of large particles, which could contaminate the plasma beam, can be controlled. The filter apparatus further comprises a set of solenoid coils which coil around the filter to generate a magnetic field to drive plasma to the targeting object or material.

The filter apparatus of this present invention can reduce a number of large particles in the plasma beam and can further be designed into compacted shapes with high flexibility for adaptation in order to suit engineering demands. In addition, the filter apparatus according to this invention does not hinder the line of sight and is in consistent with the direction of plasma movement so that large number of plasma can be obtained, resulting in a reduced electrical consumption for driving the plasma and a faster deposition rate to enable quick, high volume production of quality products at a reasonable cost.

Evaporation source, in particular for use in a sputtering process or in a vacuum arc evaporation process, preferably a cathode vacuum arc evaporation process. The evaporation source includes an inner base body which is arranged in an outer carrier body and which is arranged with respect to the outer carrier body such that a cooling space in flow communication with an inlet and an outlet is formed between the base body and the carrier body. In accordance with the invention, the cooling space includes an inflow space and an outflow space, and the inflow space is in flow communication with the outflow space via an overflow connection for the cooling of the evaporation source such that a cooling fluid can be conveyed from the inlet via the inflow space the overflow connection and the outflow space to the outlet.

Provided is an arc evaporation source equipped with a target, a ring-shaped magnetic field guide magnet and a back side magnetic field generation source. The magnetic field guide magnet is aligned in a direction perpendicular to the evaporation face of the target and has a polarity that is the magnetization direction facing forward or backward. The back side magnetic field generation source is disposed at the rear of the magnetic field guide magnet, which is at the side of the back side of the target, and forms magnetic force lines running in the direction of magnetization of the magnetic field guide magnet. The target is disposed such that the evaporation face is positioned in front of the magnetic field guide magnet.

An apparatus for generating energetic particles and application of coatings in a vacuum comprising a plasma duct surrounded by a magnetic deflecting and focusing system communicating with a primary cathodic arc plasma source in a cathode chamber and a distal anode in a coating chamber. A coating chamber comprises a substrate holder off of an optical axis of the plasma source. A set of baffles are installed along the walls of cathode chambers and the plasma duct not occupied with plasma sources and in some embodiments across the plasma stream to trap macroparticles and neutrals. A plasma duct has a deflecting portion with attached cathode chamber and a tunnel portion attached to the coating chamber. The deflecting system comprises a deflecting coil surrounding the cathode chamber having an off-set deflecting conductor spaced from the plasma duct. In one embodiment a magnetron source is magnetically coupled with cathodic arc source.

An arc source system, comprising a cooling body (12) and a holder body (3) adapted to be detachably fastened to said cooling body and for holding a cathode body (4), wherein the system comprises a membrane (2) which is arranged between the holder body and a lower portion (14) of said cooling body; and wherein said lower portion (14) of said cooling body is provided with at least one cooling fluid channel (11), and wherein said holder body (3) is provided with an inner fastening arrangement configured to be coupled with a corresponding outer fastening arrangement on a cathode body (4).