A semiconductor device manufacturing method includes: vertically arranging and storing a plurality of substrates in a processing container and forming a condition where at least an upper region or a lower region relative to a substrate disposing region where the plurality of substrates are arranged is blocked off by an adaptor; and while maintaining the condition, forming films on the plurality of substrates by performing a cycle including the following steps a predetermined number of times in a non-simultaneous manner: supplying source gas to the plurality of substrates in the processing container from the side of the substrate disposing region; discharging the source gas from the interior of the processing container via exhaust piping; supplying reaction gas to the plurality of substrates in the processing container from the side of the substrate disposing region; and discharging the reaction gas from the interior of the processing container via the exhaust piping.

The embodiments described herein generally relate to a substrate support assembly for use in a plasma processing chamber to provide non-uniform gas flow flowing between the substrate support assembly and sidewalls of the plasma processing chamber. In one embodiment, a substrate support assembly includes a substrate support assembly including a substrate support body defining at least a first side of the substrate support body, and a corner region and a center region formed in the first side of the substrate support body, wherein the corner region has a corner width that is smaller than a center width of the center region, the widths defined between a center axis and the first side of the substrate support body.

In some embodiments, an inline substrate processing tool may include a substrate carrier having a plurality of slots configured to retain a plurality of substrates parallel to each other when disposed in the slots, a first substrate processing module and a second substrate processing module disposed in a linear arrangement, wherein each substrate processing module includes an enclosure and a track that supports the substrate carrier and provides a path for the substrate carrier to move linearly through the first and second substrate processing modules, and a first gas cap disposed between the first and second substrate processing modules, wherein the first gas cap includes a first process gas conduit to provide a first process gas to the first substrate processing module, and a second process gas conduit to provide a second process gas to the second substrate processing module.

A heating apparatus including a side wall heat insulator configured to provide an inner space for receiving a reaction tube, an upper wall heat insulator covering a top portion of the side wall heat insulator, a heat generation part in an inner surface of the side wall heat insulator, and a heat compensating part on a lower surface of the upper wall heat insulator, the heat compensating part including a reflection surface in a first region on the lower surface of the upper wall heat insulator, the first region having a first emissivity less than an emissivity of the upper wall heat insulator may be provided.

According to the technique of the disclosure, there is provided a substrate processing apparatus including: a substrate retainer; a heat insulating assembly; a process chamber; a gas supplier including openings bored toward the wafer; a gas discharger including main exhaust openings bored toward the wafer; an exhaust port; an intermediate exhaust opening provided on a side wall of the process chamber at a position facing the heat insulating assembly; and a supply chamber exhaust port provided on the side wall of the process chamber at a height corresponding to the intermediate exhaust opening. The heat insulating assembly includes a constriction at a position corresponding to the intermediate exhaust opening, wherein its outer diameter is smaller than that of a portion of the heat insulating assembly above the position and that of another portion of the heat insulating assembly below the position.

A magnetic levitation system for transporting a carrier is described. The magnetic levitation system includes a base defining a transportation track, a carrier movable relative to the base along the transportation track, and a plurality of active magnetic bearings provided at the base and configured to face a guided structure of the carrier. The guided structure includes a first guided zone and a second guided zone configured to interact with the plurality of active magnetic bearings and a recessed zone. The recessed zone is arranged between the first guided zone and the second guided zone in a transport direction of the carrier and is recessed with respect to the first guided zone and the second guided zone.

A semiconductor manufacturing apparatus includes a reaction chamber configured to perform a process on a semiconductor substrate using a gas mixture comprising a first gas, and a first path configured to exhaust resultant gas that comprises the first gas from the reaction chamber. The semiconductor manufacturing apparatus further includes a first trap provided in the first path and configured to extract at least a portion of the first gas from the resultant gas, and a second path in which the trap is not provided and configured to exhaust the resultant gas from the reaction chamber.

A high throughput deposition apparatus includes a process chamber, a plurality of targets that form a first closed loop in the process chamber, wherein the first closed loop includes a long dimension defined by at least a first pair of targets and a short dimension defined by at least a second pair of targets, a first substrate carrier assembly that can hold one or more substrates and configured to receive a deposition material from the plurality of targets in the first closed loop, and a transport mechanism that can move the first substrate carrier assembly along an axial direction through the first closed loop in the first process chamber.

A substrate processing apparatus includes a process chamber in which one or more substrates are processed; and a substrate support configured to support the one or more substrates in the process chamber. The substrate support includes one or more plate-shaped structures arranged in the substrate support in a manner corresponding to the one or more substrates, and a thickness of a central portion of a plate-shaped structure among the one or more plate-shaped structures is different from a thickness of an outer peripheral portion of the plate-shaped structure located outer of the central portion.

A transport system of the in-line coater moves the substrate holder from chamber to chamber in a direction perpendicular to the axis of its rotation and in each process chamber. The system moves the substrate holder to the working area along its axis of rotation. The process chamber has a cavity the size of which is determined by the dimensions of the substrate holder and is sufficient to place technology devices and monitoring instruments in it. In the first embodiment of the in-line coater, the supporting frame of the transport system on which the substrate holder is cantilevered, is configured to move from the chamber to the chamber both in horizontal and vertical positions. In the second embodiment of the in-line coater the supporting frame is configured to move only in a vertical position, and the in-line coater comprises additionally a substrate holder return chamber.