Described herein is a technique capable of improving a film uniformity on a surface of a substrate and a film uniformity among a plurality of substrates including the substrate. According to one aspect thereof, there is provided a substrate processing apparatus including: a substrate retainer including: a product wafer support region, an upper dummy wafer support region and a lower dummy wafer support region; a process chamber in which the substrate retainer is accommodated; a first, a second and a third gas supplier; and an exhaust system. Each of the first gas and the third gas supplier includes a vertically extending nozzle with holes, wherein an upper of an uppermost hole and a lower end of a lowermost hole are arranged corresponding to an uppermost and a lowermost dummy wafer, respectively. The second gas supplier includes a nozzle with holes or a slit.

The present disclosure describes a semiconductor structure and a method for forming the same. The semiconductor structure can include a substrate, a fin structure over the substrate, a gate structure over a first portion of the fin structure, and an epitaxial region formed in a second portion of the fin structure. The epitaxial region can include a first semiconductor layer and an n-type second semiconductor layer formed over the first semiconductor layer. A lattice constant of the first semiconductor layer can be greater than that of the second semiconductor layer.

A substrate processing apparatus includes: a substrate retainer configured to support a substrate; a heat-insulating unit; a transfer chamber; and a gas supply mechanism configured to supply a gas into the transfer chamber, the gas supply mechanism including: a first gas supply mechanism configured to supply the gas into an upper region of the transfer chamber, where the substrate retainer is disposed such that the gas flows horizontally through the upper region; and a second gas supply mechanism configured to supply the gas into a lower region of the transfer chamber, where the heat-insulating unit is provided such that the gas flows downward through the lower region, wherein the first gas supply mechanism and the second gas supply mechanism are disposed along a first sidewall of the transfer chamber, and the second gas supply mechanism is disposed lower than the first gas supply mechanism.

A wafer supporting mechanism including: a wafer supporting table; and a movable part supported by the wafer supporting table, wherein the wafer supporting table includes a wafer supporting portion for transfer that stands up from a first surface opposing a back surface of a wafer to be placed and is provided further toward an inner side than an outer peripheral edge of the wafer to be placed, and the movable part includes a wafer supporting portion for film formation that is positioned further toward an outer peripheral side of the wafer to be placed than the wafer supporting portion for transfer and is relatively movable with respect to the wafer supporting table in a standing direction of the wafer supporting portion for transfer.

In a film-forming apparatus, a rotary shaft is connected to a rotary stage. A plurality of wafers are placed in a plurality of placement regions arranged in a circumferential direction with respect to a central axis line of the rotary shaft and is held by the rotary stage. The rotary stage is accommodated in an internal space of a susceptor. In this internal space, a gas supply mechanism generates a process gas flow along a direction orthogonal to the axis line from the outside of the rotary stage. A heat insulating material is installed in a heat insulating region in the internal space of the susceptor. The heat insulating region is located more outwardly from the axis line than positions in the placement regions nearest to the central axis line and more inwardly from the central axis line than positions in the placement regions farthest from the axis line.

A source gas supply apparatus that supplies a source gas into a processing container, includes: a raw material container configured to contain a raw material, and to vaporize the raw material; a source gas supply flow path configured to supply the source gas including the vaporized raw material into the processing container; a flow rate measurement part installed in the source gas supply flow path, and configured to measure a flow rate of the source gas; a diluent gas supply flow path joining a downstream side of the flow rate measurement part in the source gas supply flow path, and configured to supply a diluent gas for diluting the source gas; and a gas mixer provided at a merging portion of the source gas supply flow path and the diluent gas supply flow path, and configured to mix the source gas with the diluent gas via a Venturi effect.

A method of forming a transistor can include forming a gate mask on a substrate having a vertical location aligned with that of a transistor control gate; implanting first conductivity type dopants with the gate mask as an implant mask to form a first shallow halo region; implanting first conductivity type dopants with at least the gate mask as an implant mask to form a first deep halo region having a peak dopant concentration profile at a greater substrate depth than the first shallow halo region; forming an epitaxial layer on top of the substrate; forming a first control gate structure on the epitaxial layer; and forming a first source or drain region, of a second conductivity type, in at least the epitaxial layer to a side of the first control gate, and over the first shallow halo region and the first deep halo region.

Methods of producing arrays of thin crystal grains of layered semiconductors, including the creation of stable atomic-layer-thick to micron-thick membranes of crystalline semiconductors by chemical vapor deposition.

A vertical trench MOSFET comprising: a N-doped substrate of a III-N material; and an epitaxial layer of the III-N material grown on a top surface of the substrate, a N-doped drift region being formed in said epitaxial layer; a P-doped base layer of said III-N material, formed on top of at least a portion of the drift region; a N-doped source region of said III-N material; formed on at least a portion of the base layer; and a gate trench having at least one vertical wall extending along at least a portion of the source region and at least a portion of the base layer; wherein at least a portion of the P-doped base layer along the gate trench is a layer of said P-doped III-N material that additionally comprises a percentage of aluminum.

In a step of calculating formation conditions for the second silicon carbide layer, a formation time of the second silicon carbide layer is calculated as a value obtained by multiplying a value obtained by dividing the second thickness by the first thickness, by the first formation time, and a flow rate of a second ammonia gas in a step of forming the second silicon carbide layer by epitaxial growth is calculated as a value obtained by multiplying a value obtained by dividing the second concentration by the first concentration, by the first flow rate.