A wire grid polarizer (WGP) can have a conformal-coating to protect the WGP from at least one of the following: corrosion, dust, and damage due to tensile forces in a liquid on the WGP. The conformal-coating can include a silane conformal-coating with chemical formula (1), chemical formula (2), or combinations thereof: ##STR00001##
A method of applying a conformal-coating over a WGP can include exposing the WGP to Si(R.sup.1).sub.d(R.sup.2).sub.e(R.sup.3).sub.g. In the above WGP and method, X can be a bond to the ribs; each R.sup.1 can be a hydrophobic group; each R.sup.3, if any, can be any chemical element or group; d can be 1, 2, or 3, e can be 1, 2, or 3, g can be 0, 1, or 2, and d+e+g=4; R.sup.2 can be a silane-reactive-group; and each R.sup.6 can be an alkyl group, an aryl group, or combinations thereof.

There is provided a technique that includes (a) forming a first film having a first thickness on an underlayer by supplying a first process gas not including oxidizing gas to a substrate, wherein the first film contains silicon, carbon, and nitrogen and does not contain oxygen, and the underlayer is exposed on a surface of the substrate and is at least one selected from the group of a conductive metal-element-containing film and a nitride film; and (b) forming a second film having a second thickness larger than the first thickness on the first film by supplying a second process gas including oxidizing gas to the substrate, wherein the second film contains silicon, oxygen, and nitrogen, and wherein in (b), oxygen atoms derived from the oxidizing gas and diffuse from a surface of the first film toward the underlayer are absorbed by the first film and the first film is modified.

Methods for manufacturing a multilayer composite display cover include stacking a plurality of composite layers, each comprising an ultra-thin glass sheet covered in a polymer layer. After a cover glass sheet is placed on an exposed polymer layer, the composite layers may be bonded together. A ceramic coating may be applied to the external surfaces to increase hardness.

A method of processing a substrate that includes: loading the substrate in a processing chamber, the substrate including a raised feature of a semiconductor; forming a conformal dopant layer on the raised feature by atomic layer deposition (ALD); forming a metal layer over the raised feature; thermally treating the dopant layer to form an ultra-shallow dopant region in the raised feature by diffusion of a dopant from the dopant layer into the raised feature; and thermally treating the metal layer to form an ohmic contact region in the raised feature by diffusion of a metal from the metal layer into the raised feature.

There is provided a technique that includes (a) forming a first film having a first thickness on an underlayer by supplying a first process gas not including oxidizing gas to a substrate, wherein the first film contains silicon, carbon, and nitrogen and does not contain oxygen, and the underlayer is exposed on a surface of the substrate and is at least one selected from the group of a conductive metal-element-containing film and a nitride film; and (b) forming a second film having a second thickness larger than the first thickness on the first film by supplying a second process gas including oxidizing gas to the substrate, wherein the second film contains silicon, oxygen, and nitrogen, and wherein in (b), oxygen atoms derived from the oxidizing gas and diffuse from a surface of the first film toward the underlayer are absorbed by the first film and the first film is modified.

Provided is a plasma enhanced atomic layer deposition (PEALD) process for depositing etch-resistant SiOCN films. These films provide improved growth rate, improved step coverage and excellent etch resistance to wet etchants and post-deposition plasma treatments containing O.sub.2 and NH.sub.3 co-reactants. This PEALD process relies on one or more precursors reacting in tandem with the plasma exposure to deposit the etch-resistant thin-films of SiOCN. The films display excellent resistance to wet etching with dilute aqueous HF solutions, both after deposition and after post-deposition plasma treatment(s). Accordingly, these films are expected to display excellent stability towards post-deposition fabrication steps utilized during device manufacturing and build.

Embodiments of the present disclosure generally relate to processing a workpiece containing a substrate during deposition, etching, and/or curing processes with a mask to have localized deposition on the workpiece. A mask is placed on a first layer of a workpiece, which protects a plurality of trenches from deposition of a second layer. In some embodiments, the mask is placed before deposition of the second layer. In other embodiments, the second layer is cured before the mask is deposited. In other embodiments, the second layer is etched after the mask is deposited. Methods disclosed herein allow the deposition of a second layer in some of the trenches present in the workpiece, while at least partially preventing deposition of the second layer in other trenches present in the workpiece.

There is provided a technique that includes: (a) supplying a first gas containing a predetermined element to the substrate; (b) supplying a second gas containing carbon and nitrogen to the substrate; (c) supplying a nitrogen-containing gas activated by plasma to the substrate; (d) supplying an oxygen-containing gas to the substrate; and (e) forming a film containing at least the predetermined element, oxygen, carbon, and nitrogen on the substrate by: performing a cycle a first number of times of two or more, the cycle performing (a) to (d); or performing a cycle once or more, the cycle performing (a) to (d) in this order.

Methods and apparatus for forming an integrated circuit structure, comprising: delivering a process gas to a process volume of a process chamber; applying low frequency RF power to an electrode formed from a high secondary electron emission coefficient material disposed in the process volume; generating a plasma comprising ions in the process volume; bombarding the electrode with the ions to cause the electrode to emit electrons and form an electron beam; and contacting a dielectric material with the electron beam to cure the dielectric material, wherein the dielectric material is a flowable chemical vapor deposition product. In embodiments, the curing stabilizes the dielectric material by reducing the oxygen content and increasing the nitrogen content of the dielectric material.

Described herein is a technique capable of suppressing an adhesion of deposits to an inside of a reaction vessel of a substrate processing apparatus. According to one aspect, there is provided a substrate processing apparatus including: a substrate retainer provided with a substrate support region; a heat insulator provided below the substrate support region; and a reaction vessel of a cylindrical shape in which the substrate retainer and the heat insulator are accommodated, wherein the reaction vessel includes: an auxiliary chamber protruding outward in a radial direction of the reaction vessel and extending along an extending direction from at least a position below an upper end of the heat insulator to a position facing the substrate support region; and a first cover provided in the auxiliary chamber along a plane perpendicular to the extending direction of the auxiliary chamber so as to divide an inner space of the auxiliary chamber.