A physical vapor deposition (PVD) apparatus includes: a vacuum chamber; a pedestal arranged in the vacuum chamber and configured to support a substrate; a target arranged on the vacuum chamber and including a deposition material; a shield arranged on an inner sidewall of the vacuum chamber toprotect the vacuum chamber from the deposition material; a target power supply applying a target voltage to the target to generate plasma in the vacuum chamber; and a magnet configured to induce the plasma to the target; and a magnetic field formation line connected with the target power supply, wherein the magnetic field formation line surrounds the shield symmetrically with respect to a center of the shield to form a magnetic field in the vacuum chamber.

A deposition system, and a method of operation thereof are disclosed. The deposition system comprises a cathode assembly comprising a rotating magnet assembly including a plurality of outer peripheral magnets surrounding an inner peripheral magnet.

Embodiments of the present disclosure provide a semiconductor processing apparatus and a magnetron mechanism thereof. The magnetron mechanism is applied to the semiconductor processing apparatus and includes a backplane, an outer magnetic pole, and an inner magnetic pole. The outer magnetic pole is arranged on a bottom surface of the backplane and encloses to form accommodation space. The inner magnetic pole is arranged on the bottom surface of the backplane and located in the accommodation space. The inner magnetic pole can move to change corrosion areas of the target material. The distance between the inner magnetic pole and the outer magnetic pole is always greater than a predetermined distance during the movement. With the semiconductor processing apparatus and the magnetron mechanism thereof of embodiments of the present disclosure can achieve the full target corrosion in a sputtering environment in a high-pressure state.

A target sputtering device includes: a back plate; and a plurality of electromagnetic coil units uniformly distributed underneath the back plate and insulated with each other, wherein the plurality of electromagnetic coil units are configured to generate a magnetic field, which is movable relative to the back plate and orthogonal to the back plate, in a preset period. There is further disclosed a method for sputtering a target using the above-described target sputtering device.

A vacuum coating and plasma treatment system includes a magnetron cathode with a long edge and a short edge. The magnetic pole of the magnetron results in an electromagnetic barrier. At least one remote arc discharge is generated separate from the magnetron cathode and in close proximity to the cathode so that it is confined within a volume adjacent to the magnetron target. The remote arc discharge extends parallel to the long edge of the magnetron target and is defined by the surface of the target on one side and the electromagnetic barrier on all other sides. There is a remote arc discharge cathode hood and anode hood extending over the arc discharge and across the short edge of the magnetron cathode. Outside of the plasma assembly is a magnetic system creating magnetic field lines which extend into and confine the plasma in front of the substrate.

A method of manufacturing a component for a reference electrode assembly according to various aspects of the present disclosure includes providing a separator having first and second opposing surfaces. The method further includes sputtering a first current collector layer to the first surface via magnetron or ion beam sputtering deposition. A porosity of the separator is substantially unchanged by the sputtering. In one aspect, the method further includes sputtering a second current collector layer to the second surface via magnetron or ion beam sputtering deposition. In one aspect, the first current collector layer includes nickel and defines a first thickness of greater than or equal to about 200 nm to less than or equal to about 300 nm and the second current collector layer includes gold and defines a second thickness of greater than or equal to about 25 nm to less than or equal to about 100 nm.

A deposition system, and a method of operation thereof, includes: a cathode; a shroud below the cathode; a rotating shield below the cathode for exposing the cathode through the shroud and through a shield hole of the rotating shield; and a rotating pedestal for producing a material to form a carrier over the rotating pedestal, wherein the material having a non-uniformity constraint of less than 1% of a thickness of the material and the cathode having an angle between the cathode and the carrier.

Bulk acoustic wave resonator structures include a bulk layer with inclined c-axis hexagonal crystal structure piezoelectric material supported by a substrate. The bulk layer may be prepared without first depositing a seed layer on the substrate. The bulk material layer has a c-axis tilt of about 32 degrees or greater. The bulk material layer may exhibit a ratio of shear coupling to longitudinal coupling of 1.25 or greater during excitation. A method for preparing a crystalline bulk layer having a c-axis tilt includes depositing a bulk material layer directly onto a substrate at an off-normal incidence. The deposition conditions may include a pressure of less than 5 mTorr and a deposition angle of about 35 degrees to about 85 degrees.

Methods and apparatus for in-situ plasma cleaning of a deposition chamber are provided. In one embodiment a method for plasma cleaning a deposition chamber without breaking vacuum is provided. The method comprises positioning a substrate on a susceptor disposed in the chamber and circumscribed by an electrically floating deposition ring, depositing a metal film on the substrate and the deposition ring in the chamber, grounding the metal film deposited on the deposition ring without breaking vacuum, and removing contaminants from the chamber with a plasma formed in the chamber without resputtering the metal film on the grounded deposition ring and without breaking vacuum.

A cathode assembly for a magnetron sputtering system includes a target comprising sputterable material having an at least partially exposed, substantially planar sputtering or erosion surface and a target support configured to support and move the target during sputtering. In certain exemplary embodiments the cathode assembly further comprises a magnetic field source, e.g., a magnet array behind the target. The target support is configured to move the sputtering surface of the target by rotating or spinning the target in the plane of the sputtering surface, moving the target linearly back-and-forth or otherwise. The target support is configured to move the target relative to the magnetic field source, which may be stationary during sputtering, e.g., relative to the cathode assembly and vacuum chamber in which the sputtering is performed. A sputtering system including such a cathode assembly also is provided. A method of sputtering is further provided, employing such a cathode assembly.