A sputtering target comprising: a backing plate; and a target material bonded via a bonding material to a bonding region of the backing plate, wherein a bonding area of a bonding portion between the target material and the backing plate accounts for 97% or more of the area of the bonding region, and wherein a maximum defect area of portions without the bonding material present between the target material and the backing plate accounts for 0.6% or less of the area of the bonding region.

The sputtering target enables manufacturing of the sputtering target in which the target material is hardly peeled off during sputtering.

Apparatus for physical vapor deposition are provided herein. In some embodiments, a clamp for use in a physical vapor deposition (PVD) chamber includes a clamp body and an outwardly extending shelf that extends from the clamp body, wherein the outwardly extending shelf includes a clamping surface configured to clamp an isolator ring to a chamber body of the PVD chamber, wherein a height of the outwardly extending shelf is about 15 percent to about 40 percent of a height of the clamp body and wherein the clamp body includes a central opening configured to retain a fastener therein.

Method for building up and/or finalizing a PVD target whereas the method comprises a process step where target material is added using an additive method.

The purpose of the present invention is to improve uniformity of film deposition by a plasma-based sputtering device. Provided is a sputtering device 100 for depositing a film on a substrate W through sputtering of targets T by using plasma P, said sputtering device being provided with a vacuum chamber 2 which can be evacuated to a vacuum and into which a gas is to be introduced; a substrate holding part 3 for holding the substrate W inside the vacuum chamber 2; target holding parts 4 for holding the targets T inside the vacuum chamber 2; multiple antennas 5 which are arranged along a surface of the substrate W held by the substrate holding part 3 and generate plasma P; and a reciprocal scanning mechanism 14 for scanning back and forth the substrate holding part 3 along the arrangement direction X of the multiple antennas 5.

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 substrate processing apparatus that processes a substrate using particles, includes a conveyance mechanism configured to convey the substrate along a conveyance surface, a particle source configured to emit particles, a rotation mechanism configured to make the particle source pivot about a rotation axis, and a movement mechanism configured to move the particle source such that a distance between the particle source and the conveyance surface is changed.

A physical vapor deposition (PVD) target for performing a PVD process is provided. The PVD target includes a backing plate and a target plate coupled to the backing plate. The target plate includes a sputtering source material and a dopant, with the proviso that the dopant is not impurities in the sputtering source material. The sputtering source material includes a diffusion barrier material.

A sputtering system is suitable for sputtering a surface to be sputtered having sections. Each section has a projection height. The sputtering system includes a supporting plate, a sputtering array, and a controller. The sputtering array is arranged on the supporting plate. The sputtering array includes sputtering units. Each section corresponds to at least one of the sputtering units. Each sputtering unit has a driving shaft and a target. The target faces the surface to be sputtered. The controller is electrically connected the driving shaft. The driving shaft drives the target to move relative to the surface to be sputtered. The controller controls a distance between each sputtering unit and the corresponding section of the sections in the direction of the projection height to satisfy a given condition.

A sputtering target according to one embodiment is an integrated sputtering target comprising a target portion and a backing plate portion, both of them being made of copper and unavoidable impurities, wherein a Vickers hardness Hv is 90 or more, and wherein a flat ratio of crystal grains in a cross section orthogonal to a sputtering surface is 0.35 or more and 0.65 or less.

A hybrid additive manufacturing system a build chamber, a polymer additive manufacturing system housed within the build chamber and a physical vapor deposition (PVD) system housed within the build chamber. A controller is configured to issue control signals to the polymer additive manufacturing system and PVD system for layered deposition of polymer and PVD layers in a multilayer part.