The invention provides a sputter deposition assembly that includes a sputtering chamber, a sputtering target, and a magnet assembly. The magnet assembly includes a magnetic backing plate comprising an elongated flexible magnetic control body or a plurality of layered metal sheets.

A method is for depositing a dielectric material on to a substrate in a chamber by pulsed DC magnetron sputtering with a pulsed DC magnetron device which produces one or more primary magnetic fields. In the method, a sputtering material is sputtered from a target, wherein the target and the substrate are separated by a gap in the range 2.5 to 10 cm and a secondary magnetic field is produced within the chamber which causes a plasma produced by the pulsed DC magnetron device to expand towards one or more walls of the chamber.

A plasma deposition apparatus includes a first plasma source that can produce a plasma confined in a magnetic field. The first plasma source includes a closed-loop electrode defining a center region therein and a central axis through the central region, and one or more magnets that are outside an inner surface of the closed-loop electrode. The magnets can produce a magnetic field in the center region. The one or more magnets can be at least partially embedded in the closed-loop electrode. The closed-loop electrode and the magnets can produce a plasma of ions to sputter atoms off a sputtering target or a backing plate.

A method for treating a micro electro-mechanical system (MEMS) component is disclosed. In one example, the method includes the steps of providing a first wafer, treating the first wafer to form cavities and at least an oxide layer on a top surface of the first wafer using a first chemical vapor deposition (CVD) process, providing a second wafer, bonding the second wafer on a top surface of the at least one oxide layer, treating the second wafer to form a first plurality of structures, depositing a layer of Self-Assembling Monolayer (SAM) to a surface of the MEMS component using a second CVD process.

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 method for treating a micro electro-mechanical system (MEMS) component is disclosed. In one example, the method includes the steps of providing a first wafer, treating the first wafer to form cavities and at least an oxide layer on a top surface of the first wafer using a first chemical vapor deposition (CVD) process, providing a second wafer, bonding the second wafer on a top surface of the at least one oxide layer, treating the second wafer to form a first plurality of structures, depositing a layer of Self-Assembling Monolayer (SAM) to a surface of the MEMS component using a second CVD process.

The present disclosure provides systems and methods of controlling a magnetically confined plasma sputtering process using the waste heat transferred from the plasma into the target material and then into thermally controlled magnetic field adjustment assemblies that modify the strength of the plasma confinement magnetic fields on the target material.

A film forming apparatus for forming a film on a substrate by using a magnetron sputtering method. The film forming apparatus includes: a substrate holder configured to hold a substrate; a target holder configured to hold a target made of a ferromagnetic material to face the substrate holder; a magnet provided on a surface of the target holder opposite to the substrate holder, and configured to leak a magnetic field to a front surface of the target held by the target holder that is a surface close to the substrate holder; and a magnetic field strength measurement device configured to measure a strength of the magnetic field.

A sputtering cathode includes a magnet having a body of length L1 defining a north magnetic pole at a first end of the body and a south magnetic pole at a second, opposite end of the body. A sputtering target of length L2 surrounds the body of the magnet, but not ends of the magnet.

An apparatus has a cathode target with a cathode target outer perimeter. An inner magnet array with an inner magnet array inner perimeter is within the cathode target outer perimeter. The inner magnet array includes an inner magnet array base portion and an inner magnet array upper portion. A keeper plate assembly is connected to the inner magnet array upper portion and isolates the inner magnet array upper portion from the inner magnet array base portion. An outer magnet array is connected to a bottom surface of the keeper plate. The outer magnet array has an outer magnet array outer perimeter larger than the inner magnet array inner perimeter. The inner magnet array upper portion has a first magnetic orientation and the outer magnet array and the inner magnet array base portion have a second magnetic orientation opposite the first magnetic orientation.