A process for area selective atomic layer deposition (ALD) at the near atomic scale (sub 10 nm) is disclosed. A substrate surface is cleaned and terminated with hydrogen and a pattern written in the hydrogen terminated surface by selectively depassivating the surface using scanning tunneling microscope lithography. The depassivated regions are subjected to a halogen flux with the thus passivated regions further subjected to a functionalization process creating functionalized regions. The role of hydrogen and halogen can be inverted to invert the tone of the pattern. The substrate is then subjected to the ALD process, with growth occurring only in the non-functionalized regions. The substrate may then optionally be subjected to selective etching to remove the functionalized regions and the portions of the substrate under the functionalized regions.

A method of forming a layer includes introducing a Group III precursor in a reactor, introducing a hydride Group V precursor in the reactor, and introducing a metal-organic Group V precursor in the reactor to form the layer. The method can further include mixing the hydride Group V precursor and the metal-organic Group V precursor. Advantageously, the layer and method of forming the layer utilize mixed Group V precursors, improve uniformity, decrease thermal sensitivity of the end material, normalize concentration profiles of precursors, improve yield, increase manufacturing efficiency, improve control of III-V ratios (e.g., pressure, growth rate, flux), and reduce manufacturing costs.

A method for forming ultraviolet (UV) radiation responsive metal-oxide containing film is disclosed. The method may include, depositing an UV radiation responsive metal oxide-containing film over a substrate by, heating the substrate to a deposition temperature of less than 400 C., contacting the substrate with a first vapor phase reactant comprising a metal component, a hydrogen component, and a carbon component, and contacting the substrate with a second vapor phase reactant comprising an oxygen containing precursor, wherein regions of the UV radiation responsive metal oxide-containing film have a first etch rate after UV irradiation and regions of the UV radiation responsive metal oxide-containing film not irradiated with UV radiation have a second etch rate, wherein the second etch rate is different from the first etch rate.

Provided herein are methods and apparatuses for controlling uniformity of processing at an edge region of a semiconductor wafer. In some embodiments, the methods include exposing an edge region to treatment gases such as etch gases and/or inhibition gases. Also provided herein are exclusion ring assemblies including multiple rings that may be implemented to provide control of the processing environment at the edge of the wafer.

A method for thermal management of semiconductor devices provides a semiconductor material. A beryllium oxide (BeO) layer is epitaxially grown over the semiconductor material. A polycrystalline diamond coating is deposited over the BeO layer.

Provided are a hard mask including an amorphous boron nitride film and a method of fabricating the hard mask, and a patterning method using the hard mask. The hard mask is provided on a substrate and used for a process of patterning the substrate, and the hard mask includes an amorphous boron nitride film.

A method for forming a film, including: atomizing a raw material solution into a mist to form raw material mist; mixing raw material mist and a carrier gas to form gas mixture; placing a substrate on a placement section of susceptor; supplying gas mixture from an atomizer to the substrate to perform film formation by thermal reaction on substrate; and discharging gas mixture after the film formation through an exhaust unit, wherein in the step of supplying the gas mixture from atomizer to substrate to perform film formation by thermal reaction on the substrate, at least a part of gas mixture is supplied from a smooth section adjacent to placement section to a surface of substrate, the smooth section having a surface roughness of 200 m or less. A method for forming a film capable of uniformly and stably producing a high-quality film on a surface of a large-diameter substrate.

Embodiments of the present invention provide a method for removing a barrier layer of a metal interconnection on a wafer, which remove a single-layer metal ruthenium barrier layer. A method comprises: oxidizing step, is to oxidize the single-layer metal ruthenium barrier layer into a ruthenium oxide layer by electrochemical anodic oxidation process; oxide layer etching step, is to etch the ruthenium oxide layer with etching liquid to remove the ruthenium oxide layer. The present invention also provides a method for removing a barrier layer of a metal interconnection on a wafer, using in a structure of a process node of 10 nm and below, wherein the structure comprises a substrate, a dielectric layer, a barrier layer and a metal layer, the dielectric layer is deposited on the substrate and recessed areas are formed on the dielectric layer, the barrier layer is deposited on the dielectric layer, the metal layer is deposited on the barrier layer, wherein the metal layer is a copper layer, the barrier layer is a single-layer metal ruthenium layer, and the method comprises: thinning step, is to thin the metal layer; removing step, is to remove the metal layer; oxidizing step, is to oxidize the barrier layer, and the oxidizing step uses an electrochemical anodic oxidation process; oxide layer etching step, is to etch the oxidized barrier layer.

Methods for depositing a boron nitride film on a substrate are disclosed. More particularly, the disclosure relates to methods that can be used for depositing a boron nitride film by a PECVD process. The method comprises providing a substrate into a reaction chamber, and executing a cyclical deposition process comprising a plurality of deposition cycles, ones from the plurality of deposition cycles including providing a boron precursor into the reaction chamber and providing a deposition plasma gas into the reaction chamber.

Methods and systems for depositing vanadium and/or indium layers onto a surface of a substrate and structures and devices formed using the methods are disclosed. An exemplary method includes using a cyclical deposition process, depositing a vanadium and/or indium layer onto the surface of the substrate. The cyclical deposition process can include providing a vanadium and/or indium precursor to the reaction chamber and separately providing a reactant to the reaction chamber. The cyclical deposition process may desirably be a thermal cyclical deposition process. Exemplary structures can include field effect transistor structures, such as gate all around structures. The vanadium and/or indium layers can be used, for example, as barrier layers or liners, as work function layers, as dipole shifter layers, or the like.