Aspects of the disclosure relate to apparatus for the fabrication of waveguides. In one example, an angled ion source is utilized to project ions toward a substrate to form a waveguide which includes angled gratings. In another example, an angled electron beam source is utilized to project electrons toward a substrate to form a waveguide which includes angled gratings. Further aspects of the disclosure provide for methods of forming angled gratings on waveguides utilizing an angled ion beam source and an angled electron beam source.

An exemplary system may include a chamber configured to contain a semiconductor substrate in a processing region of the chamber. The system may include a first remote plasma unit fluidly coupled with a first access of the chamber and configured to deliver a first precursor into the chamber through the first access. The system may still further include a second remote plasma unit fluidly coupled with a second access of the chamber and configured to deliver a second precursor into the chamber through the second access. The first and second access may be fluidly coupled with a mixing region of the chamber that is separate from and fluidly coupled with the processing region of the chamber. The mixing region may be configured to allow the first and second precursors to interact with each other externally from the processing region of the chamber.

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.

Methods and apparatus for forming a thin film transistor (TFT) having a metal oxide layer. The method may include forming an amorphous metal oxide layer and treating the metal oxide layer with a silicon containing gas or plasma including Si.sup.4+ ions. The silicon treatment of the metal oxide layer helps fill the oxygen vacancies in the metal oxide channel layer, leading to a more stable TFT and preventing a negative threshold voltage in the TFT.

The present disclosure describes methods and systems for plasma-assisted etching of a metal oxide. The method includes modifying a surface of the metal oxide with a first gas, removing a top portion of the metal oxide by a ligand exchange reaction, and cleaning the surface of the metal oxide with a second gas.

Methods and apparatuses for etching semiconductor material on substrates using atomic layer etching by chemisorption, by deposition, or by both chemisorption and deposition mechanisms in combination with oxide passivation are described herein. Methods involving atomic layer etching using a chemisorption mechanism involve exposing the semiconductor material to chlorine to chemisorb chlorine onto the substrate surface and exposing the modified surface to argon to remove the modified surface. Methods involving atomic layer etching using a deposition mechanism involve exposing the semiconductor material to a sulfur-containing gas and hydrogen to deposit and thereby modify the substrate surface and removing the modified surface.

In a vacuum processing apparatus including: a vacuum container including a processing chamber therein; a plasma formation chamber; plate members being arranged between the processing chamber and the plasma formation chamber; and a lamp and a window member being arranged around the plate members, in order that a wafer and the plate members are heated by electromagnetic waves from the lamp, a bottom surface and a side surface of the window member is formed of a member transmitting the electromagnetic waves therethrough.

A plasma system and a filter device are provided. In the system, an area surrounded by a dielectric window is configured as a first chamber for accommodating plasma. A first adapter is arranged under the dielectric window. An area surrounded by the first adapter is configured as a second chamber. A lower electrode platform is placed in the second chamber to carry a workpiece. A filter member of the filter device is placed at an intersection of the first chamber and the second chamber. The filter member includes through-holes configured to filter ions from the plasma. A first extension member extends from the filter member in a first direction and is placed over the first adapter. A second extension member extends from a position of the filter member adjacent to the first extension member to an inner side of the first adapter.

A device for etching a substrate includes a first reaction chamber into which a first gas is introduced; a second reaction chamber into which a second gas is introduced; and a coil device that generates an electromagnetic alternating field. At least one first reactive species is generated by applying the electromagnetic alternating field to the first gas and at least one second reactive species is generated by applying the electromagnetic alternating field to the second gas. The device further includes a separating device that prevents a direct gas exchange between the first and second reaction chambers; an etching chamber configured to receive the substrate to be anisotropically etched; and a mixing device configured such that the reactive species enter the mixing device, are mixed together, and in the mixed state act on the substrate so as to anisotropically etch the substrate in the etching chamber.

A charged particle beam apparatus according to this invention includes: a gas introduction chamber, into which raw gas is introduced; a plasma generation chamber connected to the gas introduction chamber; a coil that is wound along an outer circumference of the plasma generation chamber and to which high-frequency power is applied; an electrode arranged at a boundary between the gas introduction chamber and the plasma generation chamber and having a plurality of through-holes formed therein; a plasma electrode that is provided apart from the electrode; a detection unit for detecting whether or not the plasma has been ignited in the plasma generation chamber; and a controller that controls, based on the result of detection by the detection unit, a voltage to be supplied to the plasma electrode in association with a predetermined pressure for supplying the raw gas.