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.

Provided is a substrate processing apparatus. The substrate processing apparatus includes a tube configured to provide a processing space, a partition wall configured to provide a discharge space in which plasma is generated, a gas supply pipe configured to supply a process gas to the discharge space, and a plurality of electrodes configured to generate plasma in the discharge space. At least one of the plurality of electrodes is disposed outside the partition wall, and at least one of the plurality of electrodes is disposed inside the partition wall.

A plasma processing apparatus includes a vacuum container, a conveyance unit including a rotator and circulating and carrying a workpiece through the conveyance path, a cylindrical member having an opening at one end extended in the direction toward the conveyance path, a window member provided at the cylindrical member, and dividing a gas space from the exterior thereof, a supply unit supplying the process gas in the gas space, and an antenna generating inductive coupling plasma on the workpiece. The supply unit supplies the process gas from plural locations where a passing time at which the surface of the rotator passes through a process region is different, and the plasma processing apparatus further includes an adjusting unit individually adjusting the supply amounts of the process gas from the plural locations of the supply unit per a unit time in accordance with the passing time.

A magnetron sputtering device comprising a substrate; a target which forms a cathode in a DC electric field and comprises an electrically conductive mixture for coating the substrate; an anode in the DC electric field; a reaction chamber in which the target and the substrate are arranged. The target is spaced apart from the substrate. The voltage source is configured to generate the DC electric field between the cathode and the anode. The mixture comprises a first material and a second material. The substrate comprises a third material. The first material is an electrically non-conductive solid. The second material is an electrically conductive solid. The third material is an electrically conductive solid.

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 pretreatment assembly includes a product support assembly and a pretreatment device. The product support assembly includes a primary support assembly, a primary drive assembly, a number of secondary support assemblies, and a secondary drive assembly. The primary drive assembly is operatively coupled to the primary support assembly. The primary drive assembly imparts a generally constant motion to the primary support assembly. Each secondary support assembly is structured to support a number of work pieces. Each secondary support assembly is movably coupled to the primary support assembly. The secondary drive assembly is operatively coupled to each secondary support assembly. The secondary drive assembly selectively imparts a motion to each secondary support assembly. The pretreatment device is disposed adjacent the product support assembly.

A method of forming a silicon nitride film on a substrate having a recess pattern formed in a surface thereof, includes: forming the silicon nitride film in conformity to the surface of the substrate by supplying each of a raw material gas containing silicon and a nitriding gas for nitriding the raw material gas into a processing container in which the substrate is accommodated; shrinking the silicon nitride film such that a thickness thereof is reduced from a bottom side toward an upper side of the recess pattern by supplying a plasmarized shaping gas for shaping the silicon nitride film to the substrate in a state where the supply of the raw material gas containing silicon into the processing container is stopped; and burying the silicon nitride film in the recess pattern by alternately and repeatedly performing the forming the silicon nitride film and the shrinking the silicon nitride film.

Apparatus for treating the surface of objects with plasma, having: an enclosure; a means for placing this enclosure under vacuum; a zone for storing objects to be treated, which is called the upstream storing zone; a zone for storing treated objects, which is called the downstream storing zone; at least two plasma treatment chambers having a means for injecting an active gas mixture, a means for creating an electrical discharge and a means for confining the plasma to the volume inside the chamber; and a means for transferring between the storing zones and the chambers, characterized in that the transferring means are conveying means defining a conveying direction, and in that the various chambers are placed one behind the other, in the conveying direction, and in that the atmospheres of the various plasma treatment chambers are not hermetically sealed off from one another.

A film formation apparatus includes a chamber which has an interior capable of being vacuumed, and which includes a lid that is openable and closable on the upper part of the chamber, a rotation table which is provided in the chamber and which and carries a workpiece in the circular trajectory, a film formation unit that deposits film formation materials by sputtering on the workpiece carried by the rotation table to form films, a shielding member which is provided with an opening at the side which the workpiece passes through, and which forms a film formation room where the film formations by the film formation units are performed, and a support which supports the shielding member, and which is independent relative to the chamber and is independent from the lid.

A vacuum treatment apparatus includes a vacuum treatment recipient with a circular opening between an inside and exterior of the recipient. The recipient houses a turntable, which defines a plane (P) along its table surface, is drivingly rotatable around a central axis perpendicular to plane (P), and exhibits a plurality of circular substrates supports. The opening is arranged such that during a turn of the turntable the area of each of the substrate supports and the opening are fully aligned and completely face each other. The vacuum treatment apparatus also includes a PVD deposition source attached to the opening. The PVD source has a a circular material target and a static magnet arrangement. The magnet arrangement is arranged in a plane (M) in parallel to plane (P) and is not rotationally symmetric around a central axis running centrally through the magnet arrangement and being perpendicular to the plane (M).