A film forming apparatus includes a chamber that is a container in which a sputter gas is introduced, a carrying unit provided inside the chamber, and circulating and carrying a work-piece on a trajectory of a circular circumference, and a film formation processing unit including a sputter source depositing, on the work-piece circulated and carried by the carrying unit, a film formation material by sputtering to form a film, and a dividing member dividing a film forming position where the film is formed on the work-piece by the sputter source. The dividing member is installed so as to divide the film forming position in a way that, in the trajectory of the circular circumference, a trajectory of passing through a region other than the film forming position performing the film formation is longer than a trajectory of passing through the film forming position performing the film formation.

Some embodiments provide a magnetron sputtering apparatus including a vacuum chamber within which a controlled environment may be established, a target comprising one or more sputterable materials, wherein the target includes a racetrack-shaped sputtering zone that extends longitudinally along a longitudinal axis and comprises a straightaway area sandwiched between a first turnaround area and a second turnaround area, a gas distribution system that supplies a first gas mixture to the first turnaround area and/or the second turnaround area and supplies a second gas mixture to the straightaway area, wherein the first gas mixture reduces a sputtering rate relative to the second gas mixture. In some cases, the first gas mixture includes inert gas having a first atomic weight and the second gas mixture includes inert gas having a second atomic weight, wherein the second atomic weight is heavier than the first atomic weight.

A device for use in a sputter system, comprising at least a first end block and a second end block positioned at opposite sides of the sputter system. The device is adapted such that a target assembly comprising at least one target tube or sputter magnetron, when mounted on the first and second end blocks, may be powered actively with RF power at both sides of the assembly, and such that the target assembly, when mounted, is not actively powered continuously with RF power simultaneously at both extremities of a target tube or sputter magnetron. An assembly comprising said device and a control unit for controlling powering of opposite sides of the target assembly by RF power such that the target assembly, when mounted, is not actively powered continuously with RF power simultaneously at both extremities of a target tube or sputter magnetron.

Some embodiments provide a magnetron sputtering apparatus including a vacuum chamber within which a controlled environment may be established, a target comprising one or more sputterable materials, wherein the target includes a racetrack-shaped sputtering zone that extends longitudinally along a longitudinal axis and comprises a straightaway area sandwiched between a first turnaround area and a second turnaround area, a gas distribution system that supplies a first gas mixture to the first turnaround area and/or the second turnaround area and supplies a second gas mixture to the straightaway area, wherein the first gas mixture reduces a sputtering rate relative to the second gas mixture. In some cases, the first gas mixture includes inert gas having a first atomic weight and the second gas mixture includes inert gas having a second atomic weight, wherein the second atomic weight is heavier than the first atomic weight.

An apparatus includes a process chamber, a substrate holder arranged in the process chamber, a first shield provided on the peripheral portion of the substrate holder, and a second shield provided inside the process chamber. The internal space of the process chamber is partitioned into an outer space and a process space to process the substrate, by at least the first shield, the second shield, and the substrate holder. The substrate holder can be driven along a driving direction perpendicular to a substrate holding surface. The length, in a direction parallel to the driving direction, of a minimum gap portion having a minimum size in a direction perpendicular to the driving direction between the first and second shields does not change even if the substrate holder is driven in the driving direction.

Implementations of the present disclosure relate to a sputtering target for a sputtering chamber used to process a substrate. In one implementation, a sputtering target for a sputtering chamber is provided. The sputtering target comprises a sputtering plate with a backside surface having radially inner, middle and outer regions and an annular-shaped backing plate mounted to the sputtering plate. The backside surface has a plurality of circular grooves which are spaced apart from one another and at least one arcuate channel cutting through the circular grooves and extending from the radially inner region to the radially outer region of sputtering plate. The annular-shaped backing plate defines an open annulus exposing the backside surface of the sputtering plate.

A rotary sputtering cathode assembly is provided that comprises a rotatable target cylinder having a first end and an opposing second end. A first power transfer apparatus is configured to carry radio frequency power to the first end of the target cylinder, and a second power transfer apparatus is configured to carry radio frequency power to the second end of the target cylinder. Radio frequency power signals are simultaneously delivered to both of the first and second ends of the target cylinder during a sputtering operation.

A cathode target assembly for use in sputtering target material onto a substrate includes a generally cylindrical target and a magnetic array. The magnetic array is adapted to provide a plasma confinement region adjacent an outer surface of the target. End portions of the magnetic array are adapted to make the shape and strength of the confinement field at the turns of the racetrack closely match the shape and strength of the confinement field along the straight part of the racetrack so as to significantly reduce cross-corner effect.

A sputtering target comprising a sputtering material and having a non-planar sputtering surface prior to erosion by use in a sputtering system, the non-planar sputtering surface having a circular shape and comprising a central axis region including a concave curvature feature at the central axis region. The central axis region having a wear profile after erosion by use in a sputtering system for at least 1000 kWhrs including a protuberance including a first outer circumferential wear surface having a first slope. A reference, protruding convex curvature feature for a reference target after sputtering use for the same time includes a second outer circumferential wear surface having a second slope. The protuberance provides a sputtered target having reduced shadowing relative to the reference, protruding convex curvature feature, wherein the first slope is less steep than a second slope.

A gas blocking layer forming apparatus comprises a vacuum chamber that provides a space where a chemical vapor deposition process and a sputtering process are performed; a holding unit that is provided at a lower side within the vacuum chamber and mounts thereon a target object on which an organic/inorganic mixed multilayer gas blocking layer is formed; a neutral particle generation unit that is provided at an upper side within the vacuum chamber and generates a neutral particle beam having a high-density flux with a current density of about 10 A/m.sup.2 or more; and common sputtering devices that are provided at both sides of the neutral particle generation unit, wherein each common sputtering device has a sputtering target of which a surface is inclined toward a surface of the target object.