Cylindrical evaporation source which includes, at an outer cylinder wall, target material to be evaporated as well as a first magnetic field source and a second magnetic field source which form at least a part of a magnet system and are arranged in an interior of the cylindrical evaporation source for generating a magnetic field. In this respect, first magnetic field source and second magnetic field source are provided at a carrier system such that a shape and/or a strength of the magnetic field can be set in a predefinable spatial region in accordance with a predefinable scheme. In embodiments, the carrier system is configured for setting the shape and/or strength of the magnetic field of the carrier system such that the first magnetic field source is arranged at a first carrier arm and is pivotable by a predefinable pivot angle (.sub.1) with respect to a first pivot axis.

Certain example embodiments relate to sputtering apparatuses that include a plurality of targets such that a first one or ones of target(s) may be used for sputtering in a first mode, while a second one or ones of target(s) may be used for sputtering in a second mode. Modes may be switched in certain example embodiments by rotating the position of the targets, e.g., such that one or more target(s) to be used protrude into the main chamber of the apparatus, while one or more target(s) to be unused are recessed into a body portion of a cathode of (e.g., integrally formed with) the sputtering apparatus. The targets may be cylindrical magnetic targets or planar targets. At least one target location also may be made to accommodate an ion beam source.

An ion source with an insertable target holder for holding a solid dopant material is disclosed. The insertable target holder includes a pocket or cavity into which the solid dopant material is disposed. When the solid dopant material melts, it remains contained within the pocket, thus not damaging or degrading the arc chamber. Additionally, the target holder can be moved from one or more positions where the pocket is at least partially in the arc chamber to one or more positions where the pocket is entirely outside the arc chamber. In certain embodiments, a sleeve may be used to cover at least a portion of the open top of the pocket.

Certain example embodiments relate to sputtering apparatuses that include a plurality of targets such that a first one or ones of target(s) may be used for sputtering in a first mode, while a second one or ones of target(s) may be used for sputtering in a second mode. Modes may be switched in certain example embodiments by rotating the position of the targets, e.g., such that one or more target(s) to be used protrude into the main chamber of the apparatus, while one or more target(s) to be unused are recessed into a body portion of a cathode of (e.g., integrally formed with) the sputtering apparatus. The targets may be cylindrical magnetic targets or planar targets. At least one target location also may be made to accommodate an ion beam source.

A sputtering device to sputter a liquid target. The sputtering device including a trough to receive a liquid target material and a device to stir or agitate the liquid target material. The device configured to degas the liquid target material or/and to dissipate solid particles or islands on a surface of the target or/and to move such particles or islands from an active surface region to a passive surface region and/or vice-versa, whereby the passive surface region is at least 50% less exposed to sputtering as the active surface region.

Methods and apparatus for physical vapor deposition (PVD) are provided herein. In some embodiments, an apparatus includes a linear PVD source to provide a stream of material flux comprising material to be deposited on a substrate; and a substrate support for supporting the substrate at a non-perpendicular angle to the linear PVD source, and wherein the substrate support and linear PVD source are movable with respect to each other either along a plane of the support surface, or along an axis that is perpendicular to the plane of the support surface, sufficiently to cause the stream of material flux to move completely over a surface of the substrate disposed on the substrate support during operation, wherein the substrate support moves on at least one of a linear slide or shaft that is supported by and travels through a gas-cushioned bearing having an inert gas as a cushioning gas.

A plasma processing apparatus includes a first electrode, a second electrode disposed to face the first electrode, a chamber, a first high-frequency power supply, a direct-current power supply, and a gas supply source. The plasma processing apparatus generates first plasma to form a film of a reaction product on the second electrode by causing the first high-frequency power supply to supply first high-frequency power to the second electrode and causing the gas supply source to supply a first gas into the chamber; and generates second plasma to sputter the film of the reaction product by causing the first high-frequency power supply to supply the first high-frequency power to the second electrode, causing the direct-current power supply to supply direct-current power to the second electrode, and causing the gas supply source to supply a second gas into the chamber.

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.

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 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.