Methods and apparatus for physical vapor deposition are provided. The apparatus, for example, includes A PVD apparatus that includes a chamber including a chamber wall; a magnetron including a plurality of magnets configured to produce a magnetic field within the chamber; a pedestal configured to support a substrate; and a target assembly comprising a target made of gold and supported on the chamber wall via a backing plate coupled to a back surface of the target so that a front surface of the target faces the substrate, wherein a distance between a back surface formed in a recess of the backing plate and a bottom surface of the plurality of magnets is about 3.95 mm to about 4.45 mm, and wherein a distance between the front surface of the target and a front surface of the substrate is about 60.25 mm to about 60.75 mm.

A sputtering target-backing plate assembly obtained by bonding a sputtering target and a backing plate using a brazing material, wherein a braze bonding layer which bonds the sputtering target and the backing plate contains a material having thermal conductivity that is higher than that of the brazing material in an amount of 5 vol % or more and 50 vol % or less, and a thickness of the braze bonding layer is 100 m or more and 700 m or less. An object is to prevent the seepage of the brazing material while maintaining the thickness of the braze bonding layer.

A process for producing a sputtering target in which a target material is diffusion-bonded to a top face of a backing plate material, the process comprising: a step of heating the top face of the target material by a hot plate while pressing from above thereby diffusion-bonding the target material to the backing plate material in such a manner that the step is performed at a center part prior to an outer peripheral part of the top face.

Systems and methods for sputtering a layer of refractory metal layer onto a barrier layer disposed on a substrate are disclosed herein. In one or more embodiments, a method of sputter depositing a tungsten structure in an integrated circuit includes: moving a substrate into a plasma processing chamber and onto a substrate support in opposition to a sputter target assembly comprising a tungsten target having no more than ten parts per million of carbon and no more than ten parts per million of oxygen present as impurities; flowing krypton into the plasma processing chamber; and exciting the krypton into a plasma to deposit, by sputtering, a tungsten film layer on a material layer of a substrate supported by the substrate support. In some embodiments, the target assembly further includes a titanium backing plate and an aluminum bonding layer disposed between the titanium backing plate and the tungsten target.

Physical vapor deposition target assemblies, PVD chambers including target assemblies and methods of manufacturing EUV mask blanks using such target assemblies are disclosed. The target assembly includes a target shield adjacent the target and surrounding the peripheral edges of the target, the target shield comprising an insulating material and a non-insulating outer peripheral fixture to secure the target shield to the assembly.

A sputtering target structure includes a body having a first side and an opposing second side. A first sputtering target is coupled to the first side of the body. The first sputtering target includes a first material. A second sputtering target is coupled to the second side of the body. The second sputtering target includes a second material. A rotation mechanism is coupled to the body and is configured to allow rotation of the body from a first orientation to a second orientation.

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 rotatable sputtering target has a target material, a back tube and a joint piece. The joint piece is disposed between the target material and the back tube. The joint piece has a compressible structure and an electrically and thermally conductive adhesive. Particularly, the compressible structure being a compressible blanket or a compressible sheet has multiple through holes and thus the electrically and thermally conductive adhesive is filled in the through holes and then directly formed between the target material and the back tube. Using the joint piece to joint the target material and the back tube not only maintains the joint strength but also elevates the tolerable power of the rotatable sputtering target, which can increase the sputtering efficiency.

A film forming apparatus for forming a thin film on a flexible substrate. The film forming apparatus forms a thin film on a flexible substrate under vacuum. The film forming apparatus includes a first zone into which a first gas is introduced and a second zone into which a second gas is introduced in a vacuum chamber. Zone separators have openings through which the flexible substrate passes. The film forming apparatus includes a mechanism that reciprocates the flexible substrate between the zones. Further, the film forming apparatus includes a mechanism that supplies a raw material gas containing metal or silicon to the first zone, and a mechanism that performs sputtering of a material containing metal or silicon as a target material in the second zone.