Described herein is a technique capable of uniformizing a quality of a film even when a processing environment changes. According to one aspect thereof, there is provided a method of manufacturing a semiconductor device, including: (a) loading a substrate into a process chamber; (b) supplying a gas to the substrate in the process chamber through a dispersion plate of a shower head while heating the dispersion plate by a shower head heater and exhausting the gas; (c) unloading the substrate; (d) measuring a temperature of the shower head before loading a subsequent substrate; and (e) comparing the temperature of the shower head after (d) with a pre-set temperature, and operating the shower head heater to control the temperature of the shower head to become close to the pre-set temperature when a difference between the temperature of the shower head and the pre-set temperature is greater than a predetermined value.

A method of manufacturing a three-dimensional system-on-chip, comprising providing a memory wafer structure with a first redistribution layer; disposing a first conductive structure and a core die structure and an input/output die structure with a second conductive structure on the first redistribution layer, the input/output die structure being disposed around the core die structure; forming a dielectric layer covering the core die structure, the input/output die structure, and the first conductive structure; removing a part of the dielectric layer and thinning the core die structure and a plurality of input/output die structures to expose the first and second conductive structures; forming a third redistribution layer on the dielectric layer, the third redistribution layer being electrically connected to the first and second conductive structures; forming a plurality of solder balls on the third redistribution layer; performing die saw. A three-dimensional system-on-chip is further provided.

A method for implementing a thin film deposition process includes: transporting a substrate into a first chamber; feeding a precursor into the first chamber, the precursor being adsorbed on a top surface of the substrate; supplying radiant energy to at least a part of the top surface of the substrate to facilitate reaction between the precursor and the top surface of the substrate; transporting the substrate with the top surface being precursor-adsorbed into a second chamber that is separated from the first chamber and that is spatially isolated from the first chamber; feeding a reactant into the second chamber, wherein reaction between the reactant and the precursor results in a thin film forming on the top surface.

Methods of forming silicon nitride on a sidewall of a feature are disclosed. Exemplary methods include providing a substrate comprising a feature comprising a sidewall surface and a surface adjacent the sidewall surface, forming a silicon oxide layer overlying the sidewall surface and the surface adjacent the sidewall surface, using a cyclical deposition process, depositing a silicon nitride layer overlying the silicon oxide layer, and exposing the silicon nitride layer to activated species generated from a hydrogen-containing gas. Exemplary methods can additionally include selectively removing a portion of the silicon nitride layer. Structures formed using the methods and systems for performing the methods are also disclosed.

A method for selectively etching silicon germanium with respect to silicon in a stack on a chuck in an etch chamber is provided. The chuck is maintained at a temperature below 15 C. The stack is exposed to an etch gas comprising a fluorine containing gas to selectively etch silicon germanium with respect to silicon.

A method of processing a substrate having a gap includes loading the substrate onto a substrate support unit, supplying an oligomeric silicon precursor and a nitrogen-containing gas to the substrate through a gas supply unit on the substrate support unit, and generating a direct plasma in a reaction space by applying a voltage to at least one of the substrate support unit and the gas supply unit, wherein a plurality of sub-steps are performed during the supplying of the oligomeric silicon precursor and the nitrogen-containing gas and the generating a direct plasma, and different plasma duty ratios are applied during the plurality of sub-steps.

Novel cyclic silicon precursors and oxidants are described. Methods for depositing silicon-containing films on a substrate are described. The substrate is exposed to a silicon precursor and a reactant to form the silicon-containing film (e.g., elemental silicon, silicon oxide, silicon nitride). The exposures can be sequential or simultaneous.

A method for producing a semiconductor power device includes forming a gate trench from a surface of the semiconductor layer toward an inside thereof. A first insulation film is formed on the inner surface of the gate trench. The method also includes removing a part on a bottom surface of the gate trench in the first insulation film. A second insulation film having a dielectric constant higher than SiO2 is formed in such a way as to cover the bottom surface of the gate trench exposed by removing the first insulation film.

Semiconductor devices and fabrication methods thereof are described. For example, a semiconductor device includes a GaN heterojunction structure disposed on a substrate. The GaN heterojunction structure includes a barrier layer disposed on a GaN layer. The semiconductor device further includes a source contact, a drain contact, and a gate electrode. The gate electrode is disposed above the GaN heterojunction structure and between the source contact and the drain contact. The semiconductor device still further includes a plurality of segments of dielectric material disposed on the barrier layer between the source contact and the drain contact.

A substrate processing method of etching a SiN film formed on the substrate includes supplying a HF gas at a processing temperature of 450 degrees C. or higher to etch the SiN film.