The present disclosure relates to a method and device for decreasing generation of surface oxide of aluminum nitride. In a physical vapor deposition process, the aluminum nitride is deposited on a substrate in a deposition chamber to form an aluminum nitride coated substrate. A cooling chamber and a cooling load lock module respectively perform a first stage cooling and a second stage cooling on the aluminum nitride coated substrate in vacuum environments, so as to prevent the aluminum nitride coated substrate with the high temperature from being exposed in an atmosphere environment to generate the surface oxide. The method and device for decreasing the generation of the surface oxide of the aluminum nitride can further eliminate crystal defects caused by that gallium nitride is deposited on the surface oxide of the aluminum nitride in the next process.

The present disclosure is a wafer support, which includes a heating unit, an insulating-and-heat-conducting unit and a conduct portion, wherein the insulating-and-heat-conducting unit is positioned between the conduct portion and the heating unit. During a deposition process, an AC bias is formed on the conduct portion to attract a plasma disposed thereabove. The heating unit includes at least one heating coil, wherein the heating coil heats the wafer supported by the wafer support via the insulating-and-heat-conducting unit and the conduct portion. The insulating-and-heat-conducting unit electrically insulates the heating unit and the conduct portion to prevent the AC flowing in the heating coil and the AC bias on the conduct portion from conducting each other, so the wafer support can generate a stable AC bias and temperature to facilitate forming an evenly-distributed thin film on the wafer supported by the wafer support.

The invention relates to a device and a method for producing layers whose layer thickness distribution can be adjusted in coating systems with horizontally rotating substrate. A very homogeneous or a specific non-homogeneous distribution can be adjusted. The particle loading is also significantly reduced. The service life is significantly higher compared to other methods. Forming of parasitic coatings is reduced.

Embodiments include a gas distribution assembly for a semiconductor processing chamber. In an embodiment, the gas distribution assembly comprises a flow ratio controller (FRC). In an embodiment, a first line from the FRC goes to an ampoule, and a second line from the FRC goes to a main line. In an embodiment, a third line from the ampoule goes to the main line. In an embodiment, a mass flow meter is coupled to the main line.

Embodiments include a gas distribution assembly for a semiconductor processing chamber. In an embodiment, the gas distribution assembly comprises a flow ratio controller (FRC). In an embodiment, a first line from the FRC goes to an ampoule, and a second line from the FRC goes to a main line. In an embodiment, a third line from the ampoule goes to the main line. In an embodiment, a mass flow meter is coupled to the main line.

A method of fabrication in a vacuum chamber. The method comprises: deploying the wafer within the vacuum chamber; applying a mask in a first position over the wafer in the vacuum chamber; following this, performing a first fabrication step comprising projecting material onto the wafer through the mask while in vacuum in the vacuum chamber; then operating a mask-handling mechanism deployed within the vacuum chamber in order to reposition the mask to a second position while remaining in vacuum in the vacuum chamber, wherein the repositioning comprises receiving readings from one or more sensors sensing a current position of the mask and based thereon aligning the current position of the mask to the second position; and following this repositioning, performing a second fabrication step comprising projecting material onto the wafer through patterned openings in the repositioned mask while still maintaining the vacuum in the vacuum chamber.

A method of fabrication in a vacuum chamber. The method comprises: deploying the wafer within the vacuum chamber; applying a mask in a first position over the wafer in the vacuum chamber; following this, performing a first fabrication step comprising projecting material onto the wafer through the mask while in vacuum in the vacuum chamber; then operating a mask-handling mechanism deployed within the vacuum chamber in order to reposition the mask to a second position while remaining in vacuum in the vacuum chamber, wherein the repositioning comprises receiving readings from one or more sensors sensing a current position of the mask and based thereon aligning the current position of the mask to the second position; and following this repositioning, performing a second fabrication step comprising projecting material onto the wafer through patterned openings in the repositioned mask while still maintaining the vacuum in the vacuum chamber.

Embodiments are directed to a method of optimizing thickness of a target material film deposited on a semiconductor substrate in a semiconductor processing chamber, wherein the semiconductor processing chamber includes a magnetic assembly positioned on the semiconductor processing chamber, the magnetic assembly including a plurality of magnetic columns within the magnetic assembly. The method includes operating the semiconductor processing chamber to deposit a film of target material on a semiconductor substrate positioned within the semiconductor processing chamber, measuring an uniformity of the deposited film, adjusting a position of one or more magnetic columns in the magnetic assembly, and operating the semiconductor processing chamber to deposit the film of the target material after adjusting position of the one or more magnetic columns.

The invention relates to a filter for filtering particles from a plasma plume. The filter includes a housing with two pass-through openings arranged in the housing wall and forming a pass-through channel for passing at least part of the plasma plume through the housing, which pass-through channel extends from one side of the housing to an opposite side of the housing, at least one primary blade arranged at a distance from and rotatable around a rotation axis, which rotation axis is parallel and spaced apart from the center line of the pass-through channel, with the path of the at least one primary blade intersecting with the pass-through channel and with the at least one primary blade having a contact surface for contact with the plasma plume, which contact surface is facing in the direction of the rotation direction, and a drain channel connecting to a drain opening arranged in the housing wall. A line extending perpendicular from both the center line of the pass-through channel and a radial line extending from the rotation axis through the center line of the pass-through channel and through the path of the at least one primary blade, extends through the drain opening.

A hybrid halide perovskite film and methods of forming a hybrid halide perovskite film on a substrate are described. The film is formed on the substrate by depositing an organic solution on a substrate, heating the substrate and the organic solution to form an organic layer on the substrate, depositing an inorganic layer on the organic layer, and heating the substrate having the inorganic layer thereon to form a hybrid halide perovskite film. In some embodiments, the hybrid halide perovskite film comprises a CH[NH.sub.2].sub.2.sup.+MX.sub.3 compound, where M is selected from the group consisting of Sn, Pb, Bi, Mg and Mn, and where X is selected from the group consisting of I, Br and Cl. In other embodiments, the hybrid halide perovskite film comprises a FAMX.sub.3 compound. Methods of forming a piezoelectric device are also disclosed.