According to embodiments of the present disclosure, a substrate heating device, a substrate heating method, and a method of manufacturing a substrate heater are provided. A substrate heating device for heating a substrate within a processing container configured to perform processing of a substrate therein includes a substrate heater including a placement surface on which the substrate is placed. The substrate heater is configured to heat the substrate placed on the placement surface using a heater. The substrate heating device further includes a jacket provided to cover a bottom portion of the substrate heater via a cooling space and a cooling gas supplier configured to supply a cooling gas to the cooling space.

A radiation shield and an assembly and a reactor including the radiation shield are disclosed. The radiation shield can be used to control heat flux from a susceptor heater assembly and thereby enable better control of temperatures across a surface of a substrate placed on a surface of the susceptor heater assembly.

A film production method for producing a layer containing a metal oxide, the film production method including: a heating step of heating a metal foil containing a first metal by bringing a part of the metal foil into contact with at least one heat generator; a first contact step of letting first gas containing a second metal to be in contact with both surfaces of the metal foil in a state where the part of the metal foil is supported; and a second contact step of letting second gas containing an oxidant to be in contact with the both surfaces of the metal foil in a state where the part of the metal foil is supported.

The disclosed methods and apparatus improve the fabrication of solid fibers and microstructures. In many embodiments, the fabrication is from gaseous, solid, semi-solid, liquid, critical, and supercritical mixtures using one or more low molar mass precursor(s), in combination with one or more high molar mass precursor(s). The methods and systems generally employ the thermal diffusion/Soret effect to concentrate the low molar mass precursor at a reaction zone, where the presence of the high molar mass precursor contributes to this concentration, and may also contribute to the reaction and insulate the reaction zone, thereby achieving higher fiber growth rates and/or reduced energy/heat expenditures together with reduced homogeneous nucleation. In some embodiments, the invention also relates to the permanent or semi-permanent recording and/or reading of information on or within fabricated fibers and microstructures. In some embodiments, the invention also relates to the fabrication of certain functionally-shaped fibers and microstructures. In some embodiments, the invention may also utilize laser beam profiling to enhance fiber and microstructure fabrication.

Method of performing atomic layer deposition. The method comprises supplying a precursor gas towards a substrate, using a deposition head including one or more gas supplies, including a precursor gas supply. The precursor gas reacts near a surface of the substrate for forming an atomic layer. The deposition head has an output face comprising the gas supplies, which at least partly faces the substrate surface during depositing the atomic layer. The output face has a substantially rounded shape defining a movement path of the substrate. The precursor-gas supply is moved relative to the substrate by rotating the deposition head while supplying the precursor gas, for depositing a stack of atomic layers while continuously moving in one direction. The surface of the substrate is kept contactless with the output face by means of a gas bearing.

Embodiments of the present disclosure generally relate to apparatus and methods for semiconductor processing, more particularly, to a thermal process chamber. The thermal process chamber includes a substrate support, a first plurality of heating elements disposed over or below the substrate support, and a spot heating module disposed over the substrate support. The spot heating module is utilized to provide local heating of cold regions on a substrate disposed on the substrate support during processing. Localized heating of the substrate improves temperature profile, which in turn improves deposition uniformity.

Described herein is a technique capable of forming a film so as to fill a recess of a substrate. According to one aspect thereof, there is provided a substrate processing apparatus including: a substrate mounting table on which a substrate is placed; an adsorption inhibiting gas supplier configured to supply an adsorption inhibiting gas onto a surface of the substrate from above the substrate mounting table; and a source gas supplier configured to supply a source gas onto the surface of the substrate from above the substrate mounting table, wherein a distance D1 between a gas supply port provided in the adsorption inhibiting gas supplier and the substrate is greater than a distance D2 between a gas supply port provided in the source gas supplier and the substrate.

In an embodiment, a susceptor ring assembly for use in a semiconductor processing tool includes: an upper ring plate having an aperture formed therethrough, the upper ring plate including: a first upper ring wall extending from the upper ring plate along the aperture; a second upper ring wall extending from the upper ring plate and concentric with the first upper ring wall; a bridge extending between the first upper ring wall and the second upper ring wall; a lower ring configured to interlock with the upper ring plate, the lower ring including: a lower ring wall concentric with the first upper ring wall, wherein the lower ring wall is configured to abut the first upper ring wall; and a lower plate parallel with the bridge and extending from the lower ring wall.

Embodiments of the present disclosure generally relate to apparatus and methods for semiconductor processing, more particularly, to a thermal process chamber. The thermal process chamber includes a substrate support, a first plurality of heating elements disposed over or below the substrate support, and a spot heating module disposed over the substrate support. The spot heating module is utilized to provide local heating of cold regions on a substrate disposed on the substrate support during processing. Localized heating of the substrate improves temperature profile, which in turn improves deposition uniformity.

A particle coating method includes a heating step of heating soft magnetic metal particles containing an amorphous phase within a temperature range of 100° C. or higher and 500° C. or lower for 0.1 hours or more and 300 hours or less, and an insulating film formation step of forming an insulating film at surfaces of the soft magnetic metal particles by a chemical vapor deposition method. The soft magnetic metal particles preferably contain the amorphous phase at 50 vol % or more.