A substrate alignment device includes first and second support members that are arranged to be opposite to each other and be spaced apart from each other in a plan view, and respectively support an outer peripheral end of a substrate from a position below the substrate. Further, the substrate alignment device includes a first pressing member that is arranged to be opposite to the first support member in a plan view, and moves the substrate by pressing one portion of the outer peripheral end of the substrate in a first direction directed from the second support member toward the first support member with the substrate supported by the first and second support members. The first support member includes a movement limiter that limits movement of the substrate in the first direction past a predetermined prescribed position.

A substrate processing system includes a vacuum transfer module; a plasma process module; a transfer robot in the vacuum transfer module; a stage in the plasma process module; a first ring disposed on the stage and a second ring disposed on the first ring to surround a substrate that is placed on the stage, the second ring having an inner diameter smaller than an inner diameter of the first ring; actuators to move support pins vertically to raise the first and the second rings and a transfer jig; and a controller configured to selectively execute a simultaneous transfer mode in which the transfer robot is caused to simultaneously transfer the first ring and the second ring and a sole transfer mode in which the transfer robot is caused to transfer only the second ring.

The present disclosure discloses a lift thimble system, a reaction chamber, and semiconductor processing equipment, including a wafer thimble device configured to lift a wafer from a base by rising or drop the wafer onto the base by descending, and a focus ring thimble device configured to lift a focus ring from an initial position of the focus ring by rising to cause an inner ring area of an upper surface of the focus ring to lift an edge area of the wafer, or cause the focus ring to return to the initial position by descending. The technical solutions of the system, the reaction chamber, and the equipment of the present disclosure improve maintenance efficiency of an abnormal situation, and double the service lifetime of the focus ring. Moreover, the technical solutions may further realize replacement of the focus ring without damaging reaction chamber vacuum to improve efficiency.

Embodiments of the disclosure relate to an apparatus and method for annealing one or more semiconductor substrates. In one embodiment, a processing chamber is disclosed. The processing chamber includes a chamber body enclosing an internal volume, a substrate support disposed in the internal volume and configured to support a substrate during processing, a gas panel configured to provide a processing fluid into the internal volume, and a temperature-controlled fluid circuit configured to maintain the processing fluid at a temperature above a condensation point of the processing fluid. The temperature-controlled fluid circuit includes a gas conduit fluidly coupled to a port on the chamber body at a first end and to the gas panel at a second end.

Systems and methods are described for integrated decomposition and scanning of a semiconducting wafer, where a single chamber is utilized for decomposition and scanning of the wafer of interest.

A cleaner comes into contact with a lower-surface center region of a substrate held by a first holder, so that the lower-surface center region is cleaned. The cleaner comes into contact with a lower-surface outer region of the substrate rotated by a second holder, so that the lower-surface outer region of the substrate is cleaned. During cleaning of the lower-surface center region, the second holder is rotated about a vertical axis while not holding the substrate. Alternatively, during cleaning of the lower-surface center region, the gas injector arranged between the cleaner and the second holder injects gas toward the substrate from a first height spaced apart from the substrate by a predetermined distance. Further, during drying of the lower-surface center region, the gas injector injects gas toward the substrate from a second height closer to the substrate than the first height.

A substrate transfer device, includes: a first planar motor installed in a first chamber and having an array of coils; a second planar motor installed in a second chamber connected to the first chamber and having an array of coils; a pair of transfer units configured to move on at least one of the first planar motor and the second planar motor and configured to transfer a substrate; and a controller configured to control supply of electric current to the coils of the first planar motor and the second planar motor.

The present disclosure provides a substrate transfer apparatus. According to an aspect of the present disclosure, the substrate transfer apparatus includes: a planar motor provided in a transfer chamber and having coils arranged therein; a transfer unit movable on the planar motor; and a control unit configured to control an energization of the coils. The transfer unit includes two bases having magnets arranged thereon and configured to be movable on the planar motor, a substrate support member configured to support a substrate, and a link mechanism configured to connect the two bases and the substrate support member to each other.

A substrate processing apparatus is disclosed. An exemplary substrate processing apparatus includes a reaction chamber; a susceptor plate positioned within the reaction chamber, constructed and arranged to support a substrate, and provided with one or more holes; a substrate lift mechanism comprising: a plurality of lift pins to support the substrate; and a lift pin support member to move the lift pins; in a vertical direction through the one or more holes; a substrate transfer robot provided with one or more robotic arms to transfer the substrate to a position above the lift pins; and a gas supply unit constructed and arranged to face the susceptor plate; wherein the gas supply unit is constructed and arranged to move in the vertical direction thereby positioning the gas supply unit in a processing position in the reaction chamber.

A failure analysis unit is a wafer conveyance unit configured to convey a wafer while holding the wafer in a semiconductor failure analysis apparatus, the wafer conveyance unit including: a placement table configured to fix a wafer at a predetermined observation position; and a wafer chuck configured to convey the wafer while holding the wafer to the observation position. The wafer chuck includes a plurality of holding members (protruding portions) provided so as to face a side surface of the wafer, and holds the wafer by sandwiching a peripheral portion of the wafer W with the plurality of holding members.