Disclosed are apparatus and methods for plasma processing on optical surfaces for anti-reflection (AR) treatments. The present disclosure enables efficient AR treatments and high performance of optical characters of materials having such AR coating. Narrow Gap Plasma Etching and Hollow Cathode Plasma Etching processes are disclosed according to some embodiment of the present invention. In some embodiments, the apparatus and methods are in combination of DC Bias Control to control physical (ion) bombardment and environment of the chamber (pressure and electric power) more closely, thus to control the processing more effectively.

The present invention relates generally to a plasma source utilizing a macro-particle reduction coating and method of using a plasma source utilizing a macro-particle reduction for deposition of thin film coatings and modification of surfaces. More particularly, the present invention relates to a plasma source comprising one or more plasma-generating electrodes, wherein a macro-particle reduction coating is deposited on at least a portion of the plasma-generating surfaces of the one or more electrodes to shield the plasma-generating surfaces of the electrodes from erosion by the produced plasma and to resist the formation of particulate matter, thus enhancing the performance and extending the service life of the plasma source.

A system for generating a plasma discharge in liquid utilizes first and second electrodes spaced apart in an interior space of a vessel holding the liquid. A channel can be defined in certain embodiments at least partially by at least one of the first and second electrodes, and an inlet in fluid communication with the interior space is configured to generate a vortical fluid flow in the vessel. A method for generating a plasma discharge in liquid is also provided.

A filament assembly can include: a button having a planar emitter region with one or more apertures extending from an emission surface of the planar emitter region to an internal surface opposite of the emission surface; an inlet electrical lead coupled to the button at a first side; an outlet electrical lead coupled to the button at a second side opposite of the first side; and a low work function object positioned adjacent to the internal surface of the planar emitter region and retained to the button. The planar emitter region can include a plurality of apertures. The low work function object can include a porous ceramic material having the barium, and may have a polished external surface. An electron gun can include the filament assembly. An additive manufacturing system can include the electron gun having the filament assembly.

A heaterless hollow cathode with high current discharge capability for use in electric propulsion devices is presented. The heaterless hollow cathode includes a thermionic emitter insert having a tubular shape and arranged inside a hollow cathode tube. The heaterless hollow cathode further includes a propellant feed tube that longitudinally extends from an upstream region of the hollow cathode tube into an inner volume of the insert. According to one aspect, an extension of the propellant feed tube into the inner volume of the insert is in a range from one quarter to three quarters of a total longitudinal length of the insert. The propellant feed tube is made of a refractory metal that is capable of withstanding temperatures above 2200 degrees C. with negligible evaporation. According to another aspect, the refractory metal is tantalum or tungsten.

The present invention relates generally to a plasma source utilizing a macro-particle reduction coating and method of using a plasma source utilizing a macro-particle reduction for deposition of thin film coatings and modification of surfaces. More particularly, the present invention relates to a plasma source comprising one or more plasma-generating electrodes, wherein a macro-particle reduction coating is deposited on at least a portion of the plasma-generating surfaces of the one or more electrodes to shield the plasma-generating surfaces of the electrodes from erosion by the produced plasma and to resist the formation of particulate matter, thus enhancing the performance and extending the service life of the plasma source.

The present invention relates generally to a plasma source utilizing a macro-particle reduction coating and method of using a plasma source utilizing a macro-particle reduction for deposition of thin film coatings and modification of surfaces. More particularly, the present invention relates to a plasma source comprising one or more plasma-generating electrodes, wherein a macro-particle reduction coating is deposited on at least a portion of the plasma-generating surfaces of the one or more electrodes to shield the plasma-generating surfaces of the electrodes from erosion by the produced plasma and to resist the formation of particulate matter, thus enhancing the performance and extending the service life of the plasma source.

A chemical vapor deposition system for coating one or more workpieces is described herein. The deposition system includes a plurality of processing chambers which may be operated independently to increase throughput of the deposition system. Each chamber includes a modular fixture that is configured to maintain the workpieces in a predetermined arrangement which allows for a hollow cathode effect to be maintained in an Interior space of the chamber. The deposition system achieves significantly faster, higher-quality deposition and more complete, conformal coverage.

There is described a carbon material comprising sp.sup.2 and sp.sup.3 hybridised carbon. Also described is a method of making a carbon material the method comprising: exposing a substrate to a flux of at least 10.sup.11 carbon ions per cm.sup.2 of substrate per 1 ms, a majority of the carbon ions having a kinetic energy of at least 10 eV. Further, electrodes comprising the carbon material are described. The electrodes may operate as an anode in Li ion battery characterised with improved specific capacity and operation life-time.

The present invention relates to a hollow cathode plasma source and to methods for surface treating or coating using such a plasma source, comprising first and second electrodes (1, 2), each electrode comprising an elongated cavity (4), wherein dimensions for at least one of the following parameters is selected so as to ensure high electron density and/or low amount of sputtering of plasma source cavity surfaces, those parameters being cavity cross section shape, cavity cross section area cavity distance (11), and outlet nozzle width (12).