Exemplary integrated cluster tools may include a factory interface including a first transfer robot. The tools may include a wet clean system coupled with the factory interface at a first side of the wet clean system. The tools may include a load lock chamber coupled with the wet clean system at a second side of the wet clean system opposite the first side of the wet clean system. The tools may include a first transfer chamber coupled with the load lock chamber. The first transfer chamber may include a second transfer robot. The tools may include a dry etch chamber coupled with the first transfer chamber. The tools may include a second transfer chamber coupled with the first transfer chamber. The second transfer chamber may include a third transfer robot. The tools may include a process chamber coupled with the second transfer chamber.

A substrate processing apparatus includes: a vacuum transfer chamber including a substrate transfer mechanism provided in a vacuum transfer space thereof to collectively hold and transfer substrates with a substrate holder; and a processing chamber having processing spaces and connected to the vacuum transfer chamber. The processing chamber includes a loading/unloading port provided on a side of the vacuum transfer chamber to allow the vacuum transfer space and the processing spaces to communicate with each other. The processing spaces include a first processing space in which a first process is performed on the substrate and a second processing space in which a second process is performed on the substrate subjected to the first process. The first and second processing spaces are arranged in a direction in which the substrate is loaded and unloaded, and the substrate holder has a length that extends over the first and second processing spaces.

An operating method of a vacuum processing apparatus for processing multiple wafers sequentially in a vacuum processing apparatus comprising multiple vacuum transfer containers, adjacent two of which are interlinked, a lock chamber inside which a wafer is housed. The multiple processing units are each subjected to of cleaning the interior thereof upon elapse of a predetermined period. In advance of processing multiple wafers, the operating method configures multiple sets of processing units to process each of the wafers from among the multiple processing units and starts processing of the wafers, delayed by a predetermined time in descending order of the number of processing units included in each of the multiple sets of processing units and in descending order of distance of the processing units included from the lock chamber.

Plasma processing apparatuses, substrate bonding systems, and substrate bonding methods are provided. The plasma processing apparatus includes a plasma process chamber that includes a process space, a load-lock chamber connected to the process space, a first vacuum pump that adjusts a pressure of the load-lock chamber, a process gas supply that supplies the process space with a process gas, and an H.sub.2O supply that supplies the process space with H.sub.2O. The plasma process chamber includes a chuck that supports a substrate and a plasma electrode to which a radio-frequency (RF) power is applied.

A processing system is provided, including a vacuum enclosure having a plurality of process windows and a continuous track positioned therein; a plurality of processing chambers attached sidewalls of the vacuum enclosures, each processing chamber about one of the process windows; a loadlock attached at one end of the vacuum enclosure and having a loading track positioned therein; at least one gate valve separating the loadlock from the vacuum enclosure; a plurality of substrate carriers configured to travel on the continuous track and the loading track; at least one track exchanger positioned within the vacuum enclosure, the track exchangers movable between a first position, wherein substrate carriers are made to continuously move on the continuous track, and a second position wherein the substrate carriers are made to transfer between the continuous track and the loading track.

An apparatus includes first load ports 2A and 2B and second load ports 2C and 2D provided in a left-right direction; a processing unit D2; an inspection module 4 provided between the first load ports 2A and 2B and the second load ports 2C and 2D; a first substrate transfer mechanism 5A provided at one side of the inspection module 4 in the left-right direction, and configured to transfer a substrate W into the processing unit D2 and a transfer container C on the first load ports 2A and 2B; a second substrate transfer mechanism 5B provided at the other side thereof, and configured to transfer the substrate W into the inspection module 4 and a transfer container C on the second load ports 2C and 2D; and a transit unit 51 for transferring the substrate W between the first and the second substrate transfer mechanisms 5A and 5B.

A vacuum substrate transport apparatus including a frame, a drive section having a drive axis, at least one arm, having an end effector for holding a substrate, having at least one degree of freedom axis effecting extension and retraction, and a bearing defining a guideway that defines the axis, the bearing including at least one rolling load bearing element disposed in a bearing case, interfacing between a bearing raceway and bearing rail to support arm loads, and effecting sliding of the case along the rail, and at least one rolling, substantially non-load bearing, spacer element disposed in the case, intervening between each of the load bearing elements, wherein the spacer element is a sacrificial buffer material compatible with sustained substantially unrestricted service commensurate with a predetermined service duty of the apparatus in a vacuum environment at temperatures over 260° C. for a specified predetermined service period.

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.

A substrate treating apparatus is provided. The substrate treating apparatus includes an atmospheric pressure transfer module provided with a first transfer robot having a first hand with a substrate placed thereon; a vacuum transfer module provided with a second transfer robot having a second hand with a substrate placed thereon; a load-lock chamber positioned between the atmospheric pressure transfer module and the vacuum transfer module, and having an inner space convertible between an atmospheric pressure and a vacuum atmosphere; a process chamber coupled to the vacuum transfer module and treating the substrate; and a ring carrier supported by the first transfer robot or the second transfer robot for a transfer of a ring member. The ring carrier comprises a plate having the ring member placed thereon and at least one leg protruding from a bottom surface of the plate and placed at the first hand or the second hand.

Embodiments of the present disclosure provide a plasma processing system, comprising: a transfer chamber, the transfer chamber including a plurality of sidewalls, each sidewall being connected with a plurality of process chambers; each process chamber including a base therein, the base including a central point; wherein at least two process chambers connected to a same sidewall form one process chamber group, wherein a first distance is provided between the central points of two bases in a first process chamber group, and a second distance is provided between the central points of two bases in a second process chamber group, the first distance being greater than the second distance; and the transfer chamber comprises a mechanical transfer device; a rotating pedestal includes two independently movable robot arms thereon, the two robot arms; and the two robot arms both include a plurality of rotating shafts and a plurality of rotating arms, wherein a remote rotating arm of each robot arm further includes an end effector for holding a substrate. The mechanical transfer device according to the present disclosure may simultaneously retrieve and place the substrate in the process chamber group with the first distance and the substrate in the process chamber group with the second distance.