Abstract: A vacuum coating apparatus includes at least a chamber, an arc discharge plasma source, a feeding-reeling unit, and a roller set. The first and second openings are connecting with the feeding or reeling unit so as to allow the substrate to enter and leave the chamber therethrough, respectively. The arc discharge plasma source located inside the chamber generates the plasma, which discharges radially from the arc discharge plasma source as its center. The roller set includes a plurality of the first rollers, which are located in the chamber and enclosing the arc discharge plasma source. A first surface of the substrate is facing the plurality of the first rollers and contacts tightly on the periphery of the first rollers so that the first rollers can rotate by the moving of the substrate. The material evaporated and emitted by the plasma is attached onto the first surface of the substrate.

Abstract: A large-area plasma generating apparatus is disclosed, which includes a reaction chamber; a first electrode disposed in the reaction chamber; a second electrode parallel with the first electrode and disposed in the reaction chamber; and a discharge region formed between the first and second electrodes and a plasma can be formed therein; wherein a travelling wave or a traveling-wave-like electromagnetic field is generated via at least one of the first and second electrodes and travels from one end of the discharge region to its opposite end, so as to uniform the plasma in the discharge region.

Abstract: Disclosed is an atmospheric-pressure double-plasma graft polymerization apparatus. The apparatus includes a workbench, an initial roller of a roll-to-roll device, an atmospheric-pressure plasma activation device, a peroxide formation device, a coating and grafting device, a drying device, a graft polymerization and curing device, a curing device and a final roller of a roll-to-roll device. The devices are sequentially provided on the workbench.

Abstract: A gas isolation chamber comprises a vacuum chamber, a first body module, a second body module and a first temperature modulator. The vacuum chamber comprises a first chamber part, a second chamber part and at least one first gas valve unit. The first body module is disposed on the inner wall of the first chamber part and has a first gas hole corresponding to the position of the first gas valve unit. The first gas hole is connected to the first gas valve unit. The second body module is disposed on the inner wall of the second chamber part such that a slit channel can be formed between the second and the first body modules. The first temperature modulator is disposed in the first body module. The gas isolation chamber is further combined with the vacuum film process chambers to form a plasma deposition apparatus for proceeding continuous deposition process.

Abstract: An apparatus provides large area atmospheric pressure plasma enhanced chemical vapor deposition without contaminations in its electrode assembly and deposited films. The apparatus consists of a large area vertical planar nitrogen plasma activation electrode assembly and its high voltage power supply, a large area vertical planar nitrogen plasma deposition electrode assembly and its high voltage power supply, a long-line uniform precursor jet apparatus, a roll-to-roll apparatus for substrate movement, and a sub-atmospheric pressure deposition chamber and its pumping apparatus.

Abstract: An atmospheric pressure plasma reactor includes a high-voltage electrode, a common grounded electrode, a bias electrode and at least one dielectric layer. The high-voltage electrode is connected to a high-voltage power supply. The common grounded electrode is used with the high-voltage electrode to discharge and therefore produce planar atmospheric plasma from reactive gas. The bias electrode is used to generate bias for attracting the ions of the planar atmospheric pressure plasma. The dielectric layer is used to suppress undesirable arc discharge during the discharging.

Abstract: An RF hollow cathode plasma source consists of a vacuum chamber, a pipe, a hollow cathode, at least two compartments, a conduit and input electrodes. The pipe is inserted into the chamber for introducing working gas into the chamber. The hollow cathode is disposed in the chamber and formed with a large number of apertures. At least two compartments are located below the hollow cathode. Each of the compartments includes small apertures for uniformly spreading the working gas into the apertures of the hollow cathode. The conduit is disposed along two sides of the hollow cathode to circulate cooling water around the hollow cathode. The plural input power leads are arranged near the hollow cathode. The input power leads, the pipe and the conduits are connected to the hollow cathode though the electrically-insulated walls of the grounded vacuum chamber.

Abstract: A plasma source comprises a vacuum chamber, a plurality of discharge tubes, a plurality of permanent magnets, a plurality of RF antennas, and an RF power distribution circuit. The RF power distribution circuit is electrically coupled to an RF power supply and each of the plurality of RF antennas. The lengths of the transmission paths between each of the plurality of RF antennas and the RF power supply are the same, so that the RF power supply can provide each of discharge tubes with the same RF power.

Abstract: A magnetron sputtering apparatus suitable for coating on a workpiece is provided. The magnetron sputtering apparatus includes a vacuum chamber, a holder, a magnetron plasma source and a high-power pulse power supply set, wherein the magnetron plasma source includes a base, a magnetron controller and a target. A reactive gas is inputted into the vacuum chamber, and the holder supporting the workpiece is disposed inside the vacuum chamber. The magnetron plasma source is disposed opposite to the workpiece, wherein the magnetron controller is disposed in the base, and the target is disposed on the base. The high-power pulse power supply set is coupled to the vacuum chamber, the magnetron plasma source and the holder, and a high voltage pulse power is inputted to the magnetron plasma source to generate plasma to coat a film on the surface of the workpiece.

Abstract: Disclosed is a method for growing a microcrystalline silicon film on a substrate. The method includes the step of disposing the substrate in a chamber, the step of vacuuming the chamber and heating the substrate, the step of introducing reacting gas into the chamber as a precursor and keeping the pressure in the chamber at a predetermined value and the step of using RF energy in the chamber to dissociate the reacting gas to form plasma for growing the microcrystalline silicon film on the substrate. The reacting gas includes SiH4/Ar mixture and H2. The ratio of SiH4/Ar mixture over H2 is 1:1 to 1:20.

Abstract: A hollow-cathode plasma generator includes a plurality of hollow cathodes joined together and connected to a power supply for generating plasma in vacuum. Each of the hollow cathodes includes at least one fillister defined therein, a fin formed on a side of the fillister, an air-circulating tunnel in communication with the fillister and a coolant-circulating tunnel defined therein. The fillister is used to contain working gas. The fin receives negative voltage from the power supply for ionizing the working gas to generate the plasma and spread the plasma in a single direction. The working gas travels into the fillister from the air-circulating tunnel. The coolant-circulating tunnel is used to circulate coolant for cooling the hollow cathode.

Abstract: An atmospheric pressure plasma reactor includes a high-voltage electrode, a common grounded electrode, a bias electrode and at least one dielectric layer. The high-voltage electrode is connected to a high-voltage power supply. The common grounded electrode is used with the high-voltage electrode to discharge and therefore produce planar atmospheric plasma from reactive gas. The bias electrode is used to generate bias for attracting the ions of the planar atmospheric pressure plasma. The dielectric layer is used to suppress undesirable arc discharge during the discharging.

Abstract: Disclosed is a n atmospheric-pressure double-plasma graft polymerization apparatus. The apparatus includes a workbench, an initial roller of a roll-to-roll device, an atmospheric-pressure plasma activation device, a peroxide formation device, a coating and grafting device, a drying device, a graft polymerization and curing device, a curing device and a final roller of a roll-to-roll device. The devices are sequentially provided on the workbench.

Abstract: A dielectric barrier discharge uses three electrodes at an atmospheric pressure. A wide discharge gap can be used and an enhanced plasma density can be achieved so that thick materials can be processed and its processing speed can also be greatly improved.

Abstract: Abstract of the disclosure The present invention provides a method and an apparatus for a glow discharge plasma surface treatment of flexible sheet materials under atmospheric pressure. The apparatus comprises electrodes, a single plasma-gas flow channel, uniform gas inlet-and-outlet devices, gas-seal devices for the horizontal movements of sheet materials and reel devices, so as to attain an uniform distribution of plasma gases in the gap between electrodes. As a result, not only a great amount of expensive plasma gas is saved, but also an uniform glow discharge plasma is generated at the lowest input power to obtain a good quality of uniform plasma treatment with continuous processing and high production.