Methods and apparatus for processing a substrate are provided herein. For example, a physical vapor deposition processing chamber comprises a chamber body defining a processing volume, a substrate support disposed within the processing volume and comprising a substrate support surface configured to support a substrate, a power supply configured to energize a target for sputtering material toward the substrate, an electromagnet operably coupled to the chamber body and positioned to form electromagnetic filed lines through a sheath above the substrate during sputtering for directing sputtered material toward the substrate, and a controller operably coupled to the physical vapor deposition processing chamber for controlling the electromagnet based on a recipe comprising a pulsing schedule for pulsing the electromagnet during operation to control directionality of ions relative to a feature on the substrate.

A nuclear fuel cladding element comprises a substrate made of a material containing zirconium and a protective coating covering the substrate on the outside. The protective coating is being made of a material containing chromium, and has a columnar microstructure composed of columnar grains and having on the outer surface thereof a microdroplet density of less than 100 per mm2.

A method includes loading a wafer into a sputtering chamber, followed by depositing a film over the wafer by performing a sputtering process in the sputtering chamber. In the sputtering process, a target is bombarded by ions that are applied with a magnetic field using a magnetron. The magnetron includes a magnetic element over the target, an arm assembly connected to the magnetic element, a hinge mechanism connecting the arm assembly and a rotational shaft. The arm assembly includes a first prong and a second prong at opposite sides of the hinge mechanism. The magnetron further includes a controller that controls motion of the first arm assembly, enabling the first prong to revolve in an orbital motion path about the first hinge mechanism while the second prong remains stationary.

A sputtering magnetron apparatus is provided. Another aspect employs a set of magnet assembly that forms a magnetic field over the target surface to confine electrons. A further aspect of a sputtering magnetron includes a side dark space shield that is made of magnetic metal which shunts the magnetic flux leaking from the side to prevent the formation of a secondary plasma around the dark space shield when it operates simultaneously with another plasma source.

Methods and apparatus for processing substrates are disclosed. In some embodiments, a process chamber for processing a substrate includes: a body having an interior volume and a target to be sputtered, the interior volume including a central portion and a peripheral portion; a substrate support disposed in the interior volume opposite the target and having a support surface configured to support the substrate; a collimator disposed in the interior volume between the target and the substrate support; a first magnet disposed about the body proximate the collimator; a second magnet disposed about the body above the support surface and entirely below the collimator and spaced vertically below the first magnet; and a third magnet disposed about the body and spaced vertically between the first magnet and the second magnet. The first, second, and third magnets are configured to generate respective magnetic fields to redistribute ions over the substrate.

A deposition system provides a feature that may reduce costs of the sputtering process by increasing a target change interval. The deposition system provides an array of magnet members which generate a magnetic field and redirect the magnetic field based on target thickness measurement data. To adjust or redirect the magnetic field, at least one of the magnet members in the array tilts to focus on an area of the target where more target material remains than other areas. As a result, more ion, e.g., argon ion bombardment occurs on the area, creating more uniform erosion on the target surface.

The present inventive concept relates to a deposition system including: a deposition device having a chamber, a seating plate located inside the chamber to seat a wafer, a magnet coupled to the underside of the seating plate, and a mask assembly located inside the chamber; and a transfer device having a load lock chamber for accommodating the wafer, an arm member for transferring the wafer from the load lock chamber to the seating plate, and a fourth driving module for moving the arm member, wherein the deposition device includes a first driving module for moving the magnet and the seating plate, a second driving module coupled to the first driving module to move the magnet, a third driving module for moving the wafer, and a control module for controlling the first driving module, the second driving module, the third driving module, and the fourth driving module.

A magnetron sputtering system includes a substrate mounted within a vacuum chamber. A plurality of cathode assemblies includes a first set of cathode assemblies and a second set of cathode assemblies, and is configured for reactive sputtering. Each cathode assembly includes a target comprising sputterable material and has an at least partially exposed planar sputtering surface. A target support is configured to support the target in the vacuum chamber and rotate the target relative to the vacuum chamber about a target axis. A magnetic field source includes a magnet array. A cathode assemblies controller assembly is operative to actuate the first set of cathode assemblies without actuating the second set of cathode assemblies, and to actuate the second set of cathode assemblies without actuating the first set of cathode assemblies.

A PVD method includes tilting a first magnetic element over a back side of a target. The first magnetic element is moved about an axis that extends through the target. Then, charged ions are attracted to bombard the target, such that particles are ejected from the target and are deposited over a surface of a wafer. By tilting the magnetic element relative to the target, the distribution of the magnetic fields can be more random and uniform.

A sputtering device includes a reaction chamber, a thimble mechanism, and a microwave heating mechanism. The reaction chamber includes a base configured to carry a workpiece. The thimble mechanism is arranged in the reaction chamber. The thimble mechanism generates a relative ascending and descending motion with the base and lifts the workpiece from the base. The microwave heating mechanism is arranged in the reaction chamber and includes a microwave transmitter and a mobile device. The mobile device is connected to the microwave transmitter and configured to move the microwave transmitter to a position under the workpiece in response to the workpiece being carried by the thimble mechanism to cause the microwave transmitter to emit microwaves to the workpiece to heat the workpiece.