There is provided a technique that includes forming a film containing silicon, oxygen, carbon, and nitrogen on a substrate by performing a cycle a predetermined number of times, the cycle including: forming a first layer containing silicon, carbon, and nitrogen by performing a set a predetermined number of times, the set including: supplying a first precursor, which contains at least two Si—N bonds and at least one Si—C bond in one molecule, to the substrate; and supplying a second precursor, which contains nitrogen and hydrogen, to the substrate; and forming a second layer by supplying an oxidant to the substrate, to thereby oxidize the first layer.

There is provided a technique that includes: forming an oxynitride film on at least one substrate by performing a cycle a predetermined number of times, the cycle including non-simultaneously performing: (a) supplying a precursor from a precursor supply part to the at least one substrate; (b) supplying an oxidizing agent from an oxidizing agent supply part to the at least one substrate; and (c) supplying a nitriding agent from a nitriding agent supply part to the at least one substrate, wherein in (b), an inert gas is supplied from an inert gas supply part, which is different from the oxidizing agent supply part, to the at least one substrate, and at least one of nitrogen concentration and refractive index of the oxynitride film formed on the at least one substrate is adjusted by controlling a flow rate of the inert gas.

Batteries, methods for recycling batteries, and methods of forming one or more electrodes for batteries are disclosed. The battery includes at least one of (i) a cathode including a nickel-rich material and a first sub-nanoscale metal oxide coating on the nickel-rich material; and (ii) an anode including an anode material and a second sub-nanoscale metal oxide coating disposed on the anode material.

There is included (a) forming a first film containing at least oxygen and carbon and having a concentration of carbon, which is 20 at % or more, on a substrate by supplying a film-forming gas to the substrate at a first temperature; and (b) modifying the first film into a second film by supplying an oxygen- and hydrogen-containing gas to the substrate on which the first film is formed, at a second temperature that is equal to or higher than the first temperature.

A deposition method according to one aspect of the present disclosure includes performing multiple execution cycles serially. Each of the multiple execution cycles includes: supplying a raw material gas into a process chamber; and supplying a reactant gas that reacts with the raw material gas. Among the multiple execution cycles, at least one execution cycle includes adjusting a pressure in the process chamber without supplying the raw material gas, and the adjusting of the pressure is performed prior to the supplying of the raw material gas.

Embodiments include devices and methods for managing network communication of an unmanned autonomous vehicle (UAV). A processor of the UAV may determine an altitude of the UAV. The processor may optionally also determine a speed or vector of the UAV. Based on the determined altitude and/or speed/vector of the UAV, the processor may adjust the communication parameter of the communication link between the UAV and a communication network. The processor may transmit signals based on the adjusted communication parameter, which may reduce radio frequency interference caused by the transmissions of the UAV with the communication network.

A device includes a semiconductor fin and a shallow trench isolation (STI) structure. The semiconductor fin extends from a semiconductor substrate. The STI structure is around a lower portion of the semiconductor fin, and the STI structure includes a liner layer and an isolation material. The liner layer includes a metal-contained ternary dielectric material. The isolation material is over the liner layer.

The present disclosure relates to a method for forming a p-metal work function nitride film having a desired p-work function on a substrate, including: adjusting one or more of a temperature of a substrate, a duration of one or more temporally separated vapor phase pulses, a ratio of a tungsten precursor to a titanium precursor, or a pressure of a reaction to tune a work function of a p-metal work function nitride film to a desired p-work function, and contacting the substrate with temporally separated vapor phase pulses of the tungsten precursor, the titanium precursor, and a reactive gas to form a p-metal work function nitride film thereon having the desired p-work function.

The invention relates to a method for fabricating a plasma etch-resistant film (1) on a surface of a substrate (2), wherein the method comprises the step of forming a film comprising an intermediate layer (4) of rare earth metal oxide, rare earth metal carbonate, or rare earth metal oxycarbonate, or any mixture thereof on a first layer (3) of rare earth metal oxide, wherein the rare earth metal is the same in the first layer and in the intermediate layer. The invention further relates to a plasma etch-resistant film and to the use thereof.

A method for depositing a ruthenium-containing film on a substrate by a cyclical deposition process is disclosed. The method may include: contacting the substrate with a first vapor phase reactant comprising a metalorganic precursor, the metalorganic precursor comprising a metal selected from the group consisting of platinum, aluminum, titanium, bismuth, zinc, and combination thereof. The method may also include; contacting the substrate with a second vapor phase reactant comprising ruthenium tetroxide, wherein the ruthenium-containing film comprises at least one of a ruthenium-platinum alloy, or a ternary ruthenium oxide. Device structures including a ruthenium-containing film deposited by the methods of the disclosure are also disclosed.