Disclosed herein is a method for producing a film of mixed yttrium and hafnium oxides, nitrides or fluorides on a substrate by an atomic layer deposition process. The process includes providing a reaction chamber containing a substrate, pulsing into the chamber an yttrium source reactant; purging the chamber with a purging material; pulsing into the chamber a co-reactant precursor; purging the chamber with a purging material (first subcycle); pulsing into the chamber a hafnium source reactant; purging the chamber with a purging material; pulsing into the chamber a co-reactant precursor; urging the chamber with a purging material (second subcycle). Each subcycle may be repeated multiple times in a super cycle.

Embodiments of wet clean chambers are provided herein. In some embodiments, a wet clean chamber includes: a deck plate; a substrate support that is rotatable and configured to support a substrate; a rotor disposed about and configured to rotate with the substrate support, wherein the rotor includes an upper fluid collection region disposed radially outward of the substrate support in position to collect fluid leaving the substrate support during processing, and wherein the upper fluid collection region includes a plurality of drain openings along a radially outward perimeter of a bottom of the upper fluid collection region; a stationary housing surrounding the rotor and having a lower fluid collection region disposed beneath the drain openings of the rotor; and one or more fluid delivery arms coupled to the deck plate and configured to deliver fluid to the substrate.

The present disclosure relates to an apparatus for trapping a reaction by-products produced during an organic film deposition process, and an object of the present disclosure is to provide a trapping apparatus having an internal trapping tower in which disc-type trapping units, which each have structure-type trapping plates having a large surface area per unit area in order to trap reaction by-products contained in an unreacted gas introduced into the trapping apparatus after an organic film deposition process, among semiconductor manufacturing processes, is performed in the process chamber, and a trapping disc configured to concentrate a flow of the gas or disperse or discharge the gas, are vertically arranged in multiple layers, such that the trapping apparatus traps the reaction by-products in the form of a thin film in a state in which the residence time of the gas is increased and uniform temperature distribution is maintained.

In a metal oxide film formation method of the present invention, the following steps are performed. In a solution vessel, a raw-material solution including aluminum as a metallic element is turned into a mist so that a raw-material solution mist is obtained. In a solution vessel provided independently of the solution vessel, a reaction aiding solution including a reaction aiding agent for formation of aluminum oxide is turned into a mist so that an aiding-agent mist is obtained. Then, the raw-material solution mist and the aiding-agent mist are fed to a nozzle provided in a reactor vessel via paths. Thereafter, the raw-material solution mist and the aiding-agent mist are mixed in the nozzle so that a mixed mist is obtained. Then, the mixed mist is fed onto a back surface of a heated P-type silicon substrate.

In a metal oxide film formation method of the present invention, the following steps are performed. In a solution vessel, a raw-material solution including aluminum as a metallic element is turned into a mist so that a raw-material solution mist is obtained. In a solution vessel provided independently of the solution vessel, a reaction aiding solution including a reaction aiding agent for formation of aluminum oxide is turned into a mist so that an aiding-agent mist is obtained. Then, the raw-material solution mist and the aiding-agent mist are fed to a nozzle provided in a reactor vessel via paths. Thereafter, the raw-material solution mist and the aiding-agent mist are mixed in the nozzle so that a mixed mist is obtained. Then, the mixed mist is fed onto a back surface of a heated P-type silicon substrate.

A method for forming a doped layer is disclosed. The doped layer may be used in a NMOS or a silicon germanium application. The doped layer may be created using an n-type halide species in a n-type dopant application, for example.

A method for forming a doped layer is disclosed. The doped layer may be used in a NMOS or a silicon germanium application. The doped layer may be created using an n-type halide species in a n-type dopant application, for example.

A SiC epitaxial wafer includes a SiC substrate and an epitaxial layer laminated on the SiC substrate, wherein the epitaxial layer contains an impurity element which determines the conductivity type of the epitaxial layer and boron which has a conductivity type different from the conductivity type of the impurity element, and the concentration of boron is less than 1.0×10.sup.14 cm.sup.−3 at any position in the plane of the epitaxial layer.

Embodiments of the present disclosure generally relate to carbon materials for battery electrodes and methods for preparing such carbon materials. More specifically, embodiments relate to methods for coating a carbon film onto nano-ordered carbon particles to produce carbon-coated particles which can be used as an anode material within a battery, such as a lithium-ion battery, a sodium-ion battery, other types of batteries. In one or more embodiments, a method for producing carbon-coated particles is provided and includes positioning nano-ordered carbon particles within a processing region of a processing chamber, purging the processing region containing the nano-ordered carbon particles with an inert gas, heating the nano-ordered carbon particles to a temperature of about 700° C. or greater during an annealing process, and depositing a carbon film on the nano-ordered carbon particles to produce carbon-coated particles during a vapor deposition process.

The invention provides process for producing a stable Si or Ge electrode structure comprising cycling a Si or Ge nanowire electrode until a structure of the Si nanowires form a continuous porous network of Si or Ge ligaments.