To improve field-effect mobility and reliability of a transistor including an oxide semiconductor film. Provided is a semiconductor device including an oxide semiconductor film. The semiconductor device includes a first insulating film, the oxide semiconductor film over the first insulating film, a second insulating film and a third insulating film over the oxide semiconductor film, and a gate electrode over the second insulating film. The oxide semiconductor film includes a first oxide semiconductor film, a second oxide semiconductor film over the first oxide semiconductor film, and a third oxide semiconductor film over the second oxide semiconductor film. The first to third oxide semiconductor films contain the same element. The second oxide semiconductor film includes a region where the crystallinity is lower than the crystallinity of one or both of the first oxide semiconductor film and the third oxide semiconductor film.

Described herein is a technique capable of suppressing a deviation in a thickness of a film formed on a substrate. According to one aspect of the technique of the present disclosure, a substrate processing apparatus includes a substrate retainer capable of supporting substrates; a cylindrical process chamber including a discharge part and supply holes; partition parts arranged in the circumferential direction to partition supply chambers communicating with the process chamber through the supply holes; nozzles provided with an ejection hole; and gas supply pipes. The supply chambers includes a first nozzle chamber and a second nozzle chamber, the process gas includes a source gas and an assist gas, the nozzles includes a first nozzle for the assist gas flows and a second nozzle disposed in the second nozzle chamber and through which the source gas flows, and the first nozzle is disposed adjacent to the second nozzle.

An exemplary semiconductor structure includes a semiconductor substrate; a plurality of metal lines on top of the semiconductor substrate, each line having a line width 5 nanometers or less: a plurality of dielectric features adjacent to the metal lines; and a plurality of metal vias on top of the metal lines. Out of a random sample of 1000 vias at least 950 vias are fully-aligned to corresponding metal lines.

A substrate processing method is provided. In the method, a substrate is provided. A monomer that is chemically bonded to the substrate is supplied onto the substrate. An initiator for polymerizing the monomer is supplied to the substrate having the supplied monomer thereon, thereby forming a polymer film.

A method for etching silicon at cryogenic temperatures is provided. The method includes forming an inert layer from condensation of a noble gas at cryogenic temperatures on exposed surfaces such as the sidewalls of a feature to passivate the sidewalls prior to the etching process. The method further includes flowing a fluorine-containing precursor gas into the chamber to form a fluorine-containing layer on the inert layer. The method further includes exposing the fluorine-containing layer and the inert layer to an energy source to form a passivation layer on the exposed portions of the substrate and exposing the substrate to ions to etch the substrate.

An electronic apparatus is provided and includes a first substrate comprising a first conductive layer; a second substrate which is opposed to the first conductive layer and is separated from the first conductive layer, the second substrate including a second conductive layer, and a first hole penetrating the second substrate; and a connecting material which electrically connects the first conductive layer and the second conductive layer via the first hole, wherein the connecting material consists of a single material; and the second conductive layer is located on the second substrate on a side opposite to a side that is opposed to the first conductive layer.

A nitride semiconductor device is disclosed. The semiconductor device is formed by a process that first deposits a silicon nitride (SiN) film on a semiconductor layer by the lower pressure chemical vapor deposition (LPCVD) technique at a temperature, then, forming an opening in the SiN film for an ohmic electrode. Preparing a photoresist on the SiN film, where the photoresist provides an opening that fully covers the opening in the SiN film, the process exposes a peripheral area around the opening of the SiN film to chlorine (Cl) plasma that may etch the semiconductor layer to form a recess therein. Metals for the ohmic electrode are filled within the recess in the semiconductor layer and the peripheral area of the SiN film. Finally, the metals are alloyed at a temperature lower than the deposition temperature of the SiN film.

A method and system for forming material within a gap on a surface of a substrate are disclosed. An exemplary method includes depositing a soluble layer on a surface of the substrate and exposing the soluble layer to a solvent to thereby form solvated material within the gap. Exemplary methods can further include drying the solvated material and/or converting the solvated or dried material to another material.

Disclosed herein are methods for manufacturing IC components using bottom-up fill of openings with a dielectric material. In one aspect, an exemplary method includes, first, depositing a solid dielectric liner on the inner surfaces of the openings using a non-flowable process, and subsequently filling the remaining empty volume of the openings with a fill dielectric using a flowable process. Such a combination method may maximize the individual strengths of the non-flowable and flowable processes due to the synergetic effect achieved by their combined use, while reducing their respective drawbacks. Assemblies and devices manufactured using such methods are disclosed as well.

Described herein is a technique capable of suppressing a deviation in a thickness of a film formed on a substrate. According to one aspect of the technique of the present disclosure, a substrate processing apparatus includes a substrate retainer capable of supporting substrates; a cylindrical process chamber including a discharge part and supply holes; partition parts arranged in the circumferential direction to partition supply chambers communicating with the process chamber through the supply holes; nozzles provided with an ejection hole; and gas supply pipes. The supply chambers includes a first nozzle chamber and a second nozzle chamber, the process gas includes a source gas and an assist gas, the nozzles includes a first nozzle for the assist gas flows and a second nozzle disposed in the second nozzle chamber and through which the source gas flows, and the first nozzle is disposed adjacent to the second nozzle.