A carrier head for a chemical mechanical polishing apparatus comprises: a base; a substrate receiving member comprising a plate portion having an outer surface for receiving a substrate and an inner surface at the back of the outer surface, a perimeter portion extended in a height direction from an edge of the plate portion, a securing portion extended from an outer part of the perimeter portion and connected to a lower part of the base, and a contact portion extended from an inner part of the perimeter portion; a contact coupling structure connected to the lower part of the base to provide a contact surface to the contact portion; and a perimeter portion pressurizing chamber formed by taking the securing portion and the contact portion as chamber walls when the contact portion contacts firmly the contact coupling structure by means of fluid pressure.

In one embodiment, a semiconductor manufacturing apparatus includes a container to contain wafers, and supporting tables provided in the container so as to be stacked on one another, and each including a supporting face that comes into contact with a wafer to support the wafer. The apparatus further includes supporting columns to join the supporting tables together and provided at positions where the supporting columns are contained inside outer circumferences of the supporting tables. The apparatus further includes a gas feeder to feed a gas to the wafers on the supporting tables, and a gas discharger to discharge the gas fed to the wafers on the supporting tables. Each of the supporting tables includes a first upper face as the supporting face, and a second upper face provided so as to surround the first upper face at a level higher than a level of the first upper face.

The present disclosure relates to a substrate processing apparatus, to which a source gas and a reactant gas are distributed, including a first exhaust line exhausting a first exhaust gas including the reactant gas and the source gas which is more than the reactant gas, a second exhaust line exhausting a second exhaust gas including the source gas and the reactant gas which is more than the source gas, a catch device installed in the first exhaust line, and a third exhaust line connected to an exhaust pump to exhaust the first exhaust gas passing through the catch device and the second exhaust gas passing through the second exhaust line.

A substrate processing apparatus, includes: a substrate holder including at least one support column to which a mounting part on which a substrate is mounted is attached and at least one auxiliary support column to which the mounting part is not attached, wherein the substrate holder is configured such that a diameter of the auxiliary support column is smaller than a diameter of the support column, and wherein the substrate holder is configured such that when the substrate is held by the mounting part, an end portion of the substrate and each of the support column is spaced apart from each other by a predetermined length.

A substrate delivery method includes receiving a substrate by protruding a plurality of pins, detecting a position of a predetermined portion of the substrate in a state where the substrate is supported by the plurality of pins, estimating a deviation amount and a deviation direction of a positional deviation between a center position of the substrate and a predetermined reference position using a detected result, tilting the substrate, and bringing the substrate into partial contact with the placing table by lowering the plurality of pins at a same speed in a state where the substrate is tilted, and disposing the substrate on the placing table while moving the center position of the substrate by the deviation amount in a direction opposite to the deviation direction by using rotation of the substrate in a vertical direction due to contact with the placing table by continuously lowering the plurality of pins.

Provided is a substrate processing apparatus. The apparatus includes: a process chamber configured to accommodate substrates which are horizontally oriented and stacked in multiple stages and process the substrates; a process gas supply unit configured to supply a process gas to the process chamber; an inert gas supply unit configured to supply an inert gas to the process chamber; and an exhaust unit configured to exhaust the process chamber. The process gas supply unit includes a process gas supply nozzle. The inert gas supply unit includes inert gas supply nozzles disposed at both sides of the process gas supply nozzle. Each of the inert gas supply nozzles includes at least one first inert gas ejection hole formed in a region where the substrates are stacked and at least one second inert gas ejection hole formed in a region where the substrates are not stacked.

Provided is a support unit. The support unit includes a support plate having a top surface in which a measurement groove is defined and on which a substrate is placed, and a sensor for measuring a pressure in the measurement groove in the state where the substrate is placed on the support plate. The measurement groove has a main measurement groove that extends from a central area of the support plate up to an edge area of the support plate.

In accordance with an exemplary embodiment, a substrate processing apparatus includes: a tube assembly having an inner space in which substrates are processed and assembled by laminating a plurality of laminates, each of which includes an injection part and an exhaust hole; a substrate holder configured to support the plurality of substrates in a multistage manner in the inner space; a supply line connected to one injection part of the plurality of laminates to supply a process gas; and an exhaust line connected to one of a plurality of exhaust holes to exhaust the process gas, and the substrate processing apparatus that has a simple structure and induces a laminar flow of the process gas to uniformly supply the process gas to a top surface of the substrate.

Semiconductor wafers with an epitaxial layer are produced in a deposition chamber by placing a substrate wafer in the edge region of the rear side of the substrate wafer onto a placement area of a susceptor; loading the deposition chamber with the susceptor and the substrate wafer lying on the susceptor by contacting the susceptor and transporting the susceptor and the substrate wafer lying on the susceptor from a load lock chamber into the deposition chamber; depositing an epitaxial layer on the substrate wafer; and unloading the deposition chamber by contacting the susceptor and transporting the susceptor and a semiconductor wafer with epitaxial layer, the semiconductor wafer having been produced in the course of depositing the epitaxial layer and lying on the susceptor, from the deposition chamber into the load lock chamber.

Described is a technique capable of reducing an effect of a substrate retainer on a substrate processing while maintaining a strength of a substrate retainer. Provided is a substrate retainer configured to support a plurality of substrates in horizontal orientation with an interval therebetween, the substrate retainer including: main support columns; and auxiliary support columns, wherein: each main support columns is provided with a substrate support member configured to support a substrate; a diameter of each of the auxiliary support columns is larger than a diameter of each of the main support columns and smaller than a length of the substrate support member; a distance between an edge of the substrate and each of the auxiliary support columns is shorter than a distance between the edge of the substrate and each of the main support columns; and all of the auxiliary support columns are not in contact with the substrate.