A substrate holder assembly including a substrate platen, the substrate platen disposed to support a substrate at a substrate position, a halo ring, the halo ring being disposed around the substrate position, and an outer halo being disposed around the halo ring and defining a first aperture, wherein the outer halo is disposed to engage the halo ring, the halo ring being disposed at least partially within the first aperture, the halo ring defining a second aperture, concentrically positioned within the first aperture, wherein the outer halo and the halo ring are formed at least partially of silicon, silicon carbide, doped silicon, quartz, and ceramic.

A confinement ring for a substrate processing system includes a lower wall, an outer wall, and an upper wall defining a plasma region within the confinement ring. A first plurality of slots is formed within the lower wall. The first plurality of slots provides fluid communication between the plasma region within the confinement ring and an environment external to the confinement ring. A recess is defined in a lower surface of the lower wall. A lower ring is arranged within the recess of the lower surface. The lower ring includes a second plurality of slots that provides fluid communication between the plasma region within the confinement ring and an environment external to the confinement ring via the first plurality of slots.

A temperature control method of a chamber of a plasma processing apparatus includes: (a) providing a substrate in the chamber; (b) measuring a pre-processing temperature of an internal component of the chamber; (c) determining a temperature control condition based on a difference between the pre-processing temperature measured in (b) and a target temperature that has been preset in advance; (d) performing a process including at least one of increasing the temperature of the internal component by a first plasma of a first processing gas and cooling the internal component by purging the chamber with a cooling gas, based on the temperature control condition; and (e) processing the substrate with a second plasma of a second processing gas.

Disclosed is a method of treating the surface of a quartz member. The method can remove a masking material generated by a chemical reaction between the quartz member and an etching solution, thereby completely removing scratches on the surface of the quartz member without interrupting the treatment process unlike existing technologies. The method also embosses the surface of the quartz member, thereby increasing the frictional resistance and surface roughness of the surface of the quartz member depending on the shape or density of protrusions on the surface. In addition, the method prevents deposits on the surface of the quartz member from peeling off.

In one exemplary embodiment, a substrate processing apparatus is provided. The substrate processing apparatus comprises: a chamber; a substrate support disposed in the chamber; a gas supply disposed in the chamber and connected to a supply source of reaction gas containing HF gas and C.sub.xH.sub.yF.sub.z gas (where x and z are integers equal to or greater than 1 and y is an integer equal to or greater than 0); and a plasma-generator configured to form a plasma from the reaction gas supplied to the chamber from the gas supply, wherein at least a portion of the chamber exposed to the plasma is made of a conductive silicon-containing material.

Oxygen controlled PVD AlN buffers for GaN-based optoelectronic and electronic devices is described. Methods of forming a PVD AlN buffer for GaN-based optoelectronic and electronic devices in an oxygen controlled manner are also described. In an example, a method of forming an aluminum nitride (AlN) buffer layer for GaN-based optoelectronic or electronic devices involves reactive sputtering an AlN layer above a substrate, the reactive sputtering involving reacting an aluminum-containing target housed in a physical vapor deposition (PVD) chamber with a nitrogen-containing gas or a plasma based on a nitrogen-containing gas. The method further involves incorporating oxygen into the AlN layer.

According to one embodiment, a semiconductor manufacturing apparatus member is used inside a chamber of a semiconductor manufacturing apparatus. The member includes a base material and a ceramic layer. The base material includes a first surface, a second surface at a side opposite to the first surface, and at least one hole extending through the first and second surfaces. The ceramic layer is a ceramic layer located on the base material. The at least one hole includes a first hole part continuous with the first surface. The ceramic layer includes a first part and a second part. The first part is located on the first surface. The first part is exposed. The second part is located on the first hole part. An arithmetical mean height Sa of a surface of the first part is less than an arithmetical mean height Sa of a surface of the second part.

Embodiments of the present disclosure generally relate to a process chamber for conformal oxidation of high aspect ratio structures. The process chamber includes a liner assembly located in a first side of a chamber body and two pumping ports located in a substrate support portion adjacent a second side of the chamber body opposite the first side. The liner assembly includes a flow divider to direct fluid flow away from a center of a substrate disposed in a processing region of the process chamber. The liner assembly may be fabricated from quartz minimize interaction with process gases, such as radicals. The liner assembly is designed to reduce flow constriction of the radicals, leading to increased radical concentration and flux. The two pumping ports can be individually controlled to tune the flow of the radicals through the processing region of the process chamber.

Embodiments of process kits for use in a process chamber are provided herein. In some embodiments, a process kit includes a slit door having an arcuate profile and including a first plate coupled to a second plate, wherein the first plate is configured to be coupled to an actuator, and wherein the second plate has a processing volume facing surface that includes silicon.

A method for making a component for use in a semiconductor processing chamber is provided. A component body is formed from a conductive material having a coefficient of thermal expansion of less than 10.0×10.sup.−6/K. A metal oxide layer is then disposed over a surface of the component body.