A process for preparing a support comprises the placing of a substrate on a susceptor in a chamber of a deposition system, the susceptor having an exposed surface not covered by the substrate; the flowing of a precursor containing carbon in the chamber at a deposition temperature so as to form at least one layer on an exposed face of the substrate, while at the same time depositing species of carbon and of silicon on the exposed surface of the susceptor. The process also comprises, directly after the removal of the substrate from the chamber, a first etch step consisting of the flowing of an etch gas in the chamber at a first etching temperature not higher than the deposition temperature so as to eliminate at least some of the species of carbon and silicon deposited on the susceptor.

A flow guide apparatus includes an upper flow guide structure configured to receive a first gas from a remote source, and a lower flow guide structure attached to the upper flow guide structure. The upper flow guide structure and the lower flow guide structure are configured to receive at least one gas from at least one remote source. The flow guide apparatus further includes a line diffuser structure disposed between the lower flow guide structure and the upper flow guide structure. The line diffuser structure has a long axis along a length of the upper flow guide structure and a short axis. The line diffuser structure includes a plurality of through holes that are configured to approximately evenly distribute the at least one gas as it is output into a reactor.

The metal material of the present disclosure includes: a metal base; and a film provided on a surface of the metal base and containing a fluorine-containing molybdenum compound, the fluorine-containing molybdenum compound being represented by the formula MoO.sub.xF.sub.y wherein x is a number from 0 to 2 and y is a number from 2 to 5.

Methods for etching a semiconductor structure and for conditioning a processing reactor in which a single semiconductor structure is treated are disclosed. An engineered polycrystalline silicon surface layer is deposited on a susceptor which supports the semiconductor structure. The polycrystalline silicon surface layer may be engineered by controlling the temperature at which the layer is deposited, by grooving the polycrystalline silicon surface layer or by controlling the thickness of the polycrystalline silicon surface layer.

Provided is a solid vaporization/supply system of metal halide for thin film deposition that reduces particle contamination. The system includes a vaporizable source material container for storing and vaporizing a metal halide and buffer tank coupled with the vaporizable source material container. The vaporizable source material container includes a container main body with a container wall; a lid body; fastening members; and joint members, wherein the container wall is configured to have a double-wall structure composed of an inner wall member and outer wall member, which allows a carrier gas to be led into the container main body via its space. The container wall is fabricated of 99 to 99.9999% copper, 99 to 99.9996% aluminum, or 99 to 99.9996% titanium, and wherein the container main body, the lid body, the fastening members, and the joint members are treated by fluorocarbon polymer coating and/or by electrolytic polishing.

Exemplary semiconductor processing methods may include forming a seasoning film on a heater of a processing chamber by a first deposition process. The method may include performing a hardmask deposition process in the processing chamber. The method may include cleaning the processing chamber by a first cleaning process. The method may include monitoring a gas produced during the first cleaning process. The method may include cleaning the processing chamber using a second cleaning process different from the first cleaning process. The method may also include monitoring the gas produced during the second cleaning process.

A method for cleaning a microwave plasma processing apparatus which has a processing container and a microwave radiation part, and which has a window part provided at a position where the microwave radiation part is disposed in the processing container, includes a cleaning step of adjusting a pressure to a pressure corresponding to a size of a cleaning target part, among parts within the processing container including a wall surface of the processing container, the microwave radiation part, and the window part, while supplying a cleaning gas, and performing a cleaning process using plasma of the cleaning gas.

Exemplary semiconductor processing chambers may include a chamber body. The chambers may include a showerhead. The chambers may include a substrate support. The substrate support may include a platen characterized by a first surface facing the showerhead. The substrate support may include a shaft coupled with the platen along a second surface of the platen opposite the first surface of the platen. The shaft may extend at least partially through the chamber body. A coating may extend conformally about the first surface of the platen, the second surface of the platen, and about the shaft.

A semiconductor wafer carrier structure includes a carrier body having a surface; a protective film covering the surface; a susceptor disposed on the carrier body; and a patterned coating film on the susceptor, wherein the patterned coating film has two or more different thicknesses, wherein patterns of the patterned coating film are symmetrically distributed with respect to a center of the susceptor.

A susceptor used in a deposition reactor provides heat input and controls the build-up of errant deposition. The susceptor heats a substrate tape within the reactor upon which one or more thin films are deposited, particularly high temperature superconductor (HTS) thin films produced in a MOCVD reactor.