A radial magnetron system for plasma surface modification and deposition of high-quality coatings for multi-dimensional structures is described. The system includes an axial electrode, a target material disposed on a portion of the axial electrode, an applied potential from an external electrical power source, and a high-current contact attached to the axial electrode for the applied potential. The system further includes a primary permanent magnet assembly comprising individual magnetic material elements configured to produce a target-region magnetic field for generating a Hall-effect dense plasma region under application of the applied potential to the axial electrode, and a magnet substrate that supports the primary permanent magnet assembly within the axial electrode. The magnet substrate is configured to provide a passageway for cooling the primary permanent magnet assembly and the axial electrode.

A plasma processing method that is executed by a plasma processing apparatus including a processing container containing a target substrate, a plurality of plasma sources, and a gas supply apparatus for supplying gas includes: supplying the gas from the gas supply apparatus into the processing container; individually controlling intensity of power introduced from each of the plurality of plasma sources into the processing container; and generating plasma of the gas by the intensity of the power introduced from each of the plurality of plasma sources and depositing a desired film on a second surface of the target substrate that is an opposite surface of a first surface of the target substrate so as to apply desired film stress to a film on the first surface.

An apparatus for the vacuum treatment of substrates in a vacuum chamber includes a substrate support device with a pylon which can be rotated about a longitudinal axis and has holding means for substrates and a plasma discharge device assigned to the pylon. The plasma discharge device includes more than two plate-shaped electrodes having excitation areas, the excitation areas of which are all oriented in the direction of the pylon and a power supply device for the excitation of a plasma discharge, by at least one electrical voltage applied to at least two of the electrodes, is provided, the excited plasma acting at least on parts of the pylon and on substrates that can be arranged on them. A process performs the vacuum coating by the apparatus.

The disclosure provides an apparatus for depositing poly(p-xylylene) onto a component (4). The apparatus comprises (i) a platen, (ii) an electrode, and (iii) a first feed means. The platen comprises an electrically conductive material, is electrically connected to an electrical power supply and is configured to support a component. The electrode is electrically insulated from the platen. The first feed means is configured to feed a poly(p-xylylene) monomer to the platen. Furthermore, the component either comprises an electrically conductive material or consists of an electrically insulating material. If the component consists of an electrically insulating material the electrical power supply is an alternating current power supply and generated an alternating electrical field which couples to the component, and is thereby able to penetrate through the component to create the plasma.

A plasma etching method using a Faraday cage, which effectively produces a blazed grating pattern.

A system for treating an object with plasma includes a vacuum processing chamber having a holder on which the object to be treated is placed, at least two subassemblies each including at least one plasma source able to generate a plasma and being supplied with radio-frequency power Pi and with a gas i of independent flow rate ni. The plasma generated by one of the subassemblies is a partially ionized gas or gas mixture of different chemical nature from the plasma generated by the other subassembly or subassemblies. A process for selectively treating a composite object employing such a device is described.

An apparatus for plasma treatment of an implant prior to installing the implant in a live subject is provided. The apparatus comprises an activation device and a portable container detachable from the activation device. The portable container comprises a closed compartment containing the implant immersed in a fluid, and the activation device comprises a slot configured to receive the portable container. The activation device further comprises an electrical circuit configured to be electrically associated with at least one electrode and configured to provide to the at least one electrode electric power suitable for applying a plasma generating electric field in the closed compartment, when the portable container is disposed in the slot. A container suitable for providing plasma treatment to a silicone implant and a method for preparing an implant for implantation surgery are also provided.

This application relates to a double-sided deposition apparatus and method. The double-sided deposition apparatus includes: a chamber; an upper electrode disposed in the chamber and including a first showerhead, wherein the first showerhead is configured to provide a first reaction gas to an upper surface of a wafer, to form a first plasma region between the upper electrode and the upper surface of the wafer; and a lower electrode disposed in the chamber and including a second showerhead, wherein the second showerhead is configured to provide a second reaction gas to a lower surface of the wafer, to form a second plasma region between the lower electrode and the lower surface of the wafer, and wherein a period during which the first showerhead provides the first reaction gas at least partially overlaps a period during which the second showerhead provides the second reaction gas.

An apparatus for plasma treatment of an implant prior to installing the implant in a live subject is provided. The apparatus comprises an activation device and a portable container detachable from the activation device. The portable container comprises a closed compartment containing the implant immersed in a fluid, and the activation device comprises a slot configured to receive the portable container. The activation device further comprises an electrical circuit configured to be electrically associated with at least one electrode and configured to provide to the at least one electrode electric power suitable for applying a plasma generating electric field in the closed compartment, when the portable container is disposed in the slot. A container suitable for providing plasma treatment to a silicone implant and a method for preparing an implant for implantation surgery are also provided.

The invention provides an apparatus for treating surfaces of a container. The apparatus comprises an openable reaction chamber housing, an exhaust escapement and an electrode assembly. The electrode assembly comprises a probe assembly coupled with a power source, the probe assembly comprising an elongate wand body, and a helically configured primary electrode and a helically configured counter electrode disposed about an outer circumferential surface of the wand body in an alternating helical configuration. The elongate wand body has a fluid passageway defined therewithin, and one or more outlet openings that are formed on an outer circumferential surface of the wand body and that extend inward through said outer circumferential surface and upto the fluid passageway. One or both of the primary electrode and the counter electrode may be energizable by the power source.