A sputtering apparatus includes a placement portion where a target having a first opening is placed, an anode, and a metal member. The anode and the metal member are disposed at positions corresponding to the first opening of the target in the placement portion. The anode and the metal member are electrically insulated from each other. The metal member is set to a ground potential or a floating potential.

The invention relates to a method and a device to for applying a layer 64 to a body 60, 62, and to a coated body 60. The body 60, 62 is disposed in a vacuum chamber 12 and process gas is supplied. A plasma is generated in the vacuum chamber 12 by operating a cathode 30 by applying a cathode voltage V.sub.P with cathode pulses and by sputtering a target 32. A bias voltage V.sub.B is applied to the body 60, 62 so that charge carriers of the plasma are accelerated into the direction of the body 60, 62 and attached to its surface. In order to achieve favorable properties of the coating 64 in a controlled way, the time course of the bias voltage V.sub.B is varied during the coating duration D. In the coating 64 of the body 60, 62, the material of the layer 64 comprises proportions of a noble gas, the concentration of which in the layer 64 varies over the layer thickness.

A PVD apparatus can be operated in a cleaning mode to remove material from an electrically conductive feature formed on a semiconductor substrate. The semiconductor substrate with the electrically conductive feature formed thereon is positioned on a substrate support in a chamber of the PVD apparatus. A shutter is deployed within the chamber to divide the chamber into a first compartment in which the semiconductor substrate and the substrate support are positioned, and a second compartment in which a target of the PVD apparatus is positioned. A first plasma is generated in the first compartment to remove material from the electrically conductive feature and a second plasma is simultaneously generated in the second compartment to clean the target.

An electrically and magnetically enhanced ionized physical vapor deposition (I-PVD) magnetron apparatus and method is provided for sputtering material from a cathode target on a substrate, and in particular, for sputtering ceramic and diamond-like coatings. The electrically and magnetically enhanced magnetron sputtering source has unbalanced magnetic fields that couple the cathode target and additional electrode together. The additional electrode is electrically isolated from ground and connected to a power supply that can generate positive, negative, or bipolar high frequency voltages, and is preferably a radio frequency (RF) power supply. RF discharge near the additional electrode increases plasma density and a degree of ionization of sputtered material atoms.

A film forming system comprises a chamber, a stage, a holder, a cathode magnet, a shield, a first moving mechanism, and a second moving mechanism. The chamber provides a processing space. The stage is provided in the processing space and configured to support a substrate. The holder is configured to hold a target that is provided in the processing space. The cathode magnet is provided outside the chamber with respect to the target. The shield has a slit and is configured to block particles released from the target around the slit. The first moving mechanism is configured to move the shield between the stage and the target along a scanning direction substantially parallel to a surface of the substrate mounted on the stage. The second moving mechanism is configured to move the cathode magnet along the scanning direction.

A film forming apparatus for forming a film by magnetron sputtering includes a substrate support supporting the substrate, a holder holding a target for emitting sputtered particles, a magnet unit having a magnet, first and second movement mechanisms configured to periodically move the substrate support and the magnet unit, respectively, and a controller. The controller is configured to control the first movement mechanism and the second movement mechanism so that a phase in a periodic movement of the substrate support remains the same at a start of film formation and at an end of film formation, a phase in a periodic movement of the magnet unit remains the same at a start of film formation and at an end of film formation, and the phase in the periodic movement of the substrate support and the phase in the periodic movement of the magnet unit do not match during film formation.

A sputter deposition apparatus including: a remote plasma generation arrangement arranged to provide a plasma for sputter deposition of target material within a sputter deposition zone; a confining arrangement arranged to provide a confining magnetic field to substantially confine the plasma in the sputter deposition zone a substrate provided within the sputter deposition zone; and one or more target support assemblies arranged to support one or more targets in the sputter deposition zone so as to provide for sputter deposition of the target material on the substrate. The confining arrangement confines the remote plasma to the target support assemblies such that in use there is deposited: target material as a first region on the substrate; target material as a second region on the substrate; and an intermediate region between the first and second region with no target material.

Certain examples described herein relate to a sputter deposition apparatus including a guiding member to guide a substrate in a conveyance direction, a plasma source to generate a plasma, and a magnet arrangement. The magnet arrangement is configured to confine the plasma within the apparatus to a pre-treatment zone, within which the substrate is exposed to the plasma in use. The magnet arrangement is also configured to confine the plasma within the apparatus to a sputter deposition zone, located after the pre-treatment zone in the conveyance direction, to provide for sputter deposition of a target material to the substrate in use. The pre-treatment and sputter deposition zones are disposed about the guiding member.

A sputter deposition apparatus including: a plasma generation arrangement arranged to provide single plasma for sputter deposition of target material within a sputter deposition zone; a conveyor system arranged to convey a substrate through the sputter deposition zone in a conveyance direction; and one or more target support assemblies arranged to support one or more targets in the sputter deposition zone so as to provide for sputter deposition of the target material on the substrate utilising the plasma such that as the substrate is conveyed through the sputter deposition zone in use there is deposited: a first stripe on the substrate; and a second stripe on the substrate. The first stripe includes at least one of: a different density of the target material or a different composition of the target material than the second stripe.

A sputter deposition apparatus including: a remote plasma generation arrangement arranged to provide a plasma for sputter deposition of target material within a sputter deposition zone; a confining arrangement arranged to provide a confining magnetic field to substantially confine the plasma in the sputter deposition zone a substrate provided within the sputter deposition zone; and one or more target support assemblies arranged to support one or more targets in the sputter deposition zone so as to provide for sputter deposition of the target material on the substrate. The confining arrangement confines the remote plasma to the target support assemblies such that in use there is deposited: target material as a first region on the substrate; target material as a second region on the substrate; and an intermediate region between the first and second region including a blend of target materials.