A substrate processing method includes a protective film forming step, an insulating material depositing step, a protective film removing step, and a metal material depositing step. In the protective film forming step, a protective film is formed on a metal film among the metal film and an insulating film exposed on the surface of a substrate, using a film-forming material that is selectively adsorbed onto the metal film. In the insulating material depositing step, after the protective film forming step, an insulating material is deposited on the surface of the insulating film using an atomic layer deposition method. In the protective film removing step, the protective film is removed from the surface of the metal film after the insulating material depositing step. In the metal material depositing step, a metal material is deposited on the metal film after the protective film removing step.

A thin-film transistor element including a gate layer, an oxide semiconductor thin-film, a gate insulating film disposed between the gate layer and the oxide semiconductor thin-film, a pair of source-drain electrodes electrically connected to the oxide semiconductor thin-film, and a resin film covering the oxide semiconductor thin-film is provided. The oxide semiconductor thin-film contains two or more metal elements selected from indium, gallium, zinc, and tin. The resin film is in contact with the oxide semiconductor thin-film. The resin film may include a compound that contains a SiH group. The resin film may be formed by applying a composition including a SiH group-containing compound onto the oxide semiconductor thin-film, and heating the composition.

A semiconductor component includes: a SiC semiconductor body; a trench extending from a first surface of the SiC semiconductor body into the SiC semiconductor body, the trench having a conductive connection structure, a structure width at a bottom of the trench, and a dielectric layer covering sidewalls of the trench; a shielding region along the bottom and having a central section which has a lateral first width; and a contact formed between the conductive connection structure and the shielding region. The conductive connection structure is electrically connected to a source electrode. In at least one doping plane extending approximately parallel to the bottom, a dopant concentration in the central section deviates by not more than 10% from a maximum value of the dopant concentration in the shielding region in the doping plane. The first width is less than the structure width and is at least 30% of the structure width.

A semiconductor component includes: a SiC semiconductor body; a trench extending from a first surface of the SiC semiconductor body into the SiC semiconductor body, the trench having a conductive connection structure, a structure width at a bottom of the trench, and a dielectric layer covering sidewalls of the trench; a shielding region along the bottom and having a central section which has a lateral first width; and a contact formed between the conductive connection structure and the shielding region. The conductive connection structure is electrically connected to a source electrode. In at least one doping plane extending approximately parallel to the bottom, a dopant concentration in the central section deviates by not more than 10% from a maximum value of the dopant concentration in the shielding region in the doping plane. The first width is less than the structure width and is at least 30% of the structure width.

A method of forming a silicon carbide-containing film on a substrate, includes: heating the substrate; supplying a carbon precursor gas containing an organic compound having an unsaturated carbon bond to the heated substrate; supplying a silicon precursor gas containing a silicon compound to the heated substrate; laminating, on the substrate, a silicon carbide-containing layer to be turned into the silicon carbide-containing film by allowing the organic compound having the unsaturated carbon bond to thermally react with the silicon compound; and supplying plasma to the silicon carbide-containing layer.

A method of forming a silicon carbide-containing film on a substrate, includes: heating the substrate; supplying a carbon precursor gas containing an organic compound having an unsaturated carbon bond to the heated substrate; supplying a silicon precursor gas containing a silicon compound to the heated substrate; laminating, on the substrate, a silicon carbide-containing layer to be turned into the silicon carbide-containing film by allowing the organic compound having the unsaturated carbon bond to thermally react with the silicon compound; and supplying plasma to the silicon carbide-containing layer.

A substrate processing method includes: a step of preparing a substrate in a chamber of a substrate processing apparatus; a step of correcting a set power value based on a correction value Y from Equation (1), coefficients A, B, C, and D, and a variable X indicating a processed amount of the substrates having been subjected to continuous film formation processes, referring to a storage in which the coefficients A, B, C, and D of the Equation (1) used to calculate the correction value Y for the set power value are stored; and a step of processing the prepared substrate by applying power with the corrected power value into the chamber, the Equation (1) is expressed as Y=Aexp(BX)+CX+D, where at least one of the coefficients A, C, and D is not zero, and when the coefficient A is not zero, the coefficient B is also not zero.

According to one aspect of the technique of the present disclosure, there is provided a substrate processing apparatus including: a process vessel constituting a process chamber; a first gas supplier provided with a first supply port through which a first process gas is supplied; a second gas supplier provided with a second supply port through which a second process gas is supplied; a plasma generator provided along an outer circumference of the process vessel and configured to be capable of plasma-exciting the first process gas supplied into the process chamber; and a substrate mounting table on which a substrate is placed. The second supply port is provided at a supply pipe extending downward from a position in a ceiling surface of the process chamber located closer to a radial center of the process vessel than the first supply port, and is provided below the first supply port.

There is provided a technique that includes: a cylindrical outer tube; an inner tube that is installed inside the outer tube and configured such that a substrate is capable of being processed in a process chamber formed in the inner tube; a manifold that is installed below the outer tube and the inner tube, in fluid communication with an internal space of the inner tube, and formed in a cylindrical shape with an exhaust space isolated from an annular space between the inner tube and the outer tube; a process gas nozzle configured to supply a process gas that processes the substrate to an inside of the inner tube; a purge gas nozzle configured to supply a purge gas to the annular space; and a conductance changer that is installed at a partition wall between the annular space and the exhaust space.

There is provided a technique that includes: forming a film on a substrate including a recess formed on a surface of the substrate by performing a cycle a predetermined number of times, the cycle including: (a) supplying a precursor gas to the substrate; and (b) supplying a reaction gas to the substrate, wherein in (a), the precursor gas is supplied to the substrate separately a plurality of times, and a processing condition under which the precursor gas is supplied for a first time is set to a processing condition under which self-decomposition of the precursor gas is capable of being more suppressed than a processing condition under which the precursor gas is supplied for at least one subsequent time after the first time.