Methods and apparatus for controlling the ion fraction in physical vapor deposition processes are disclosed. In some embodiments, a process chamber for processing a substrate having a given diameter includes: an interior volume and a target to be sputtered, the interior volume including a central portion and a peripheral portion; a rotatable magnetron above the target to form an annular plasma in the peripheral portion; a substrate support disposed in the interior volume to support a substrate having the given diameter; a first set of magnets disposed about the body to form substantially vertical magnetic field lines in the peripheral portion; a second set of magnets disposed about the body and above the substrate support to form magnetic field lines directed toward a center of the support surface; a first power source to electrically bias the target; and a second power source to electrically bias the substrate support.

Apparatus and methods for reducing and eliminating accumulation of excessive charged particles from substrate processing systems are provided herein. In some embodiments a process kit for a substrate process chamber includes: a cover ring having a body and a lip extending radially inward from the body, wherein the body has a bottom, a first wall, and a second wall, and wherein a first channel is formed between the second wall and the lip; a grounded shield having a lower inwardly extending ledge that terminates in an upwardly extending portion configured to interface with the first channel of the cover ring; and a bias power receiver coupled to the body and extending through an opening in the grounded shield.

Embodiments of a process kit for use in a multi-cathode process chamber are disclosed herein. In some embodiments, a process kit includes a rotatable shield having a base, a conical portion extend downward and radially outward from the base, and a collar portion extending radially outward from a bottom of the conical portion; an inner deposition ring having a leg portion, a flat portion extending radially inward from the leg portion, a first recessed portion extending radially inward from the flat portion, and a first lip extending upward from an innermost section of the first recessed portion; and an outer deposition ring having a collar portion, an upper flat portion disposed above and extending radially inward from the collar portion, a second recessed portion extending inward from the upper flat portion, and a second lip extending upward from an innermost section of the second recessed portion.

A rotary cathode assembly includes a cathode having a tube shape and defining a hollow center, a shield surrounding the cathode, the shield defining an access opening that exposes a portion of the cathode, and a rotary magnet subassembly disposed within the hollow center of the cathode. The rotary magnet subassembly includes a first magnetic component having a first magnetic field strength and a second magnetic component having a second magnetic field strength. The first magnetic field strength is greater than the second magnetic field strength. Characteristically, the first magnet component and the second magnetic component are rotatable between a first position in which the first magnetic component faces the access opening and a second position in which the second magnetic component faces the access opening. A coating system including the rotary cathode assembly is also provided.

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 plasma processing apparatus includes a chamber (20) and a target (25) above the chamber (20). The surface of the target (25) contacts the processing area of the chamber (20). The chamber (20) includes an insulating sub-chamber (21) and a first conductive sub-chamber (22), which are superposed. The first conductive sub-chamber (22) is provided under the insulating sub-chamber (21). The insulating sub-chamber (21) is made of insulating material, and the first conductive sub-chamber (22) is made of metal material. A Faraday shield component (10) which is made of metal material or insulating material electroplated with conductive coatings and includes at least one slit is provided in the insulating sub-chamber (21). An inductance coil (13) surrounds the exterior of the insulating sub-chamber (21). The problem about the wafer contamination due to particles formed on the surface of the coil during the sputtering process can be solved by using the plasma processing apparatus.

Methods and apparatus for processing substrates with a multi-cathode chamber. The multi-cathode chamber includes a shield with a plurality of holes and a plurality of shunts. The shield is rotatable to orient the holes and shunts with a plurality of cathodes located above the shield. The shunts interact with magnets from the cathodes to prevent interference during processing. The shield can be raised and lowered to adjust gapping between a target of a cathode and a hole to provide a dark space during processing.

There is provided a film forming apparatus comprising a processing chamber including a processing chamber main body and a lid, a stage, a target, and a shield. The shield has a chamber shield fixed to the processing chamber main body and a target shield fixed to the lid. The chamber shield has a cylindrical sidewall and a horizontal wall formed at a radially outer side of the cylindrical sidewall. The target shield has a cylindrical portion extending toward the stage. A diameter of an outer peripheral surface of the cylindrical portion is smaller than a diameter of an inner peripheral surface of the cylindrical sidewall, and the cylindrical portion and the cylindrical sidewall form a double pipe structure in which the cylindrical portion and the cylindrical sidewall overlap at least partially in a height direction.

Methods and apparatus for controlling the ion fraction in physical vapor deposition processes are disclosed. In some embodiments, a physical vapor deposition chamber includes: a body having an interior volume and a lid assembly including a target to be sputtered; a magnetron disposed above the target, wherein the magnetron is configured to rotate a plurality of magnets about a central axis of the physical vapor deposition chamber; a substrate support disposed in the interior volume opposite the target and having a support surface configured to support a substrate; a collimator disposed between the target and the substrate support, the collimator having a central region having a first thickness and a peripheral region having a second thickness less than the first thickness; a first power source coupled to the target to electrically bias the target; and a second power source coupled to the substrate support to electrically bias the substrate support.

The sputtering cathode has a tubular shape having a pair of long sides facing each other in cross-sectional shape, has a sputtering target whose erosion surface faces inward, and a magnetic circuit is provided along the sputtering target. The pair of long sides are constituted by rotary targets each having a cylindrical shape. The rotary target is internally provided with a magnetic circuit and configured to allow the flow of cooling water. The magnetic circuit is provided parallel to the central axis of the rotary target and has a rectangular cross-sectional shape having a long side perpendicular to the radial direction of the rotary target.