A film forming apparatus for forming a film by magnetron sputtering includes a substrate support supporting the substrate, a holder holding a target for emitting sputtered particles, a magnet unit having a magnet, first and second movement mechanisms configured to periodically move the substrate support and the magnet unit, respectively, and a controller. The controller is configured to control the first movement mechanism and the second movement mechanism so that a phase in a periodic movement of the substrate support remains the same at a start of film formation and at an end of film formation, a phase in a periodic movement of the magnet unit remains the same at a start of film formation and at an end of film formation, and the phase in the periodic movement of the substrate support and the phase in the periodic movement of the magnet unit do not match during film formation.

A film forming apparatus for forming a film by magnetron sputtering includes a substrate support supporting the substrate, a holder holding a target for emitting sputtered particles, a magnet unit having a magnet, first and second movement mechanisms configured to periodically move the substrate support and the magnet unit, respectively, and a controller. The controller is configured to control the first movement mechanism and the second movement mechanism so that a phase in a periodic movement of the substrate support remains the same at a start of film formation and at an end of film formation, a phase in a periodic movement of the magnet unit remains the same at a start of film formation and at an end of film formation, and the phase in the periodic movement of the substrate support and the phase in the periodic movement of the magnet unit do not match during film formation.

Aspects of the disclosure provided herein generally provide a substrate processing system that includes: a processing chamber including: a top plate having an array of process station openings disposed therethrough surrounding a central axis, a bottom plate having a first central opening, and a plurality of side walls between the top plate and the bottom plate; a plurality of heaters disposed in the top plate and the bottom plate and configured in a plurality of regions; and a system controller configured to independently control the plurality of heaters in each region.

Aspects of the disclosure provided herein generally provide a substrate processing system that includes: a processing chamber including: a top plate having an array of process station openings disposed therethrough surrounding a central axis, a bottom plate having a first central opening, and a plurality of side walls between the top plate and the bottom plate; a plurality of heaters disposed in the top plate and the bottom plate and configured in a plurality of regions; and a system controller configured to independently control the plurality of heaters in each region.

A physical vapor deposition processing chamber is described. The processing chamber includes a target backing plate in a top portion of the processing chamber, a substrate support in a bottom portion of the processing chamber, a deposition ring positioned at an outer periphery of the substrate support and a shield. The substrate support has a support surface spaced a distance from the target backing plate to form a process cavity. The shield forms an outer bound of the process cavity. In-chamber cleaning methods are also described. In an embodiment, the method includes closing a bottom gas flow path of a processing chamber to a process cavity, flowing an inert gas from the bottom gas flow path, flowing a reactant into the process cavity through an opening in the shield, and evacuating the reaction gas from the process cavity.

A physical vapor deposition processing chamber is described. The processing chamber includes a target backing plate in a top portion of the processing chamber, a substrate support in a bottom portion of the processing chamber, a deposition ring positioned at an outer periphery of the substrate support and a shield. The substrate support has a support surface spaced a distance from the target backing plate to form a process cavity. The shield forms an outer bound of the process cavity. In-chamber cleaning methods are also described. In an embodiment, the method includes closing a bottom gas flow path of a processing chamber to a process cavity, flowing an inert gas from the bottom gas flow path, flowing a reactant into the process cavity through an opening in the shield, and evacuating the reaction gas from the process cavity.

An apparatus for manufacturing a display apparatus includes a deposition source, a nozzle head, a substrate fixer, and a deposition preventer. The deposition source is outside the chamber and vaporizes or sublimates a deposition material. The nozzle head is in the chamber, is connected to the at least one deposition source, and simultaneously sprays the deposition material onto an entire surface of a display substrate. The substrate fixer is connected to the chamber and moves linearly, with the display apparatus is mounted on the substrate fixer. The deposition preventer is in the chamber surrounding an edge portion of the nozzle head and an edge portion of the substrate fixer. The deposition preventer is heated during a deposition process.

A surface acoustic wave device includes a piezoelectric single crystal substrate and an electrode. The piezoelectric single crystal substrate is made of LiTaO.sub.3 or LiNbO.sub.3. The electrode includes a titanium film formed on the piezoelectric single crystal substrate and an aluminum film or a film containing aluminum as a main component. The aluminum film or the film is formed on the titanium film. The aluminum film or the film containing aluminum as the main component is a twin crystal film or a single crystal film, the aluminum film or the film has a (111) plane that is non-parallel to a surface of the piezoelectric single crystal substrate with an angle θ, and the aluminum film or the film has a [−1, 1, 0] direction parallel to an X-direction of a crystallographic axis of the piezoelectric single crystal substrate.

A sputtering apparatus including a chamber, a gas supply configured to supply the chamber with a first gas and a second inert gas, the first inert gas and the second inert gas having a first evaporation point and second evaporation point, respectively, a plurality of sputter guns in an upper portion of the chamber, a chuck in a lower portion of the chamber and facing the sputter guns, the chuck configured to accommodate a substrate thereon, and a cooling unit connected to a lower portion of the chuck, the cooling unit configured to cool the chuck to a temperature less than the first evaporation point and greater than the second evaporation point, and a method of fabricating a magnetic memory device may be provided.

The disclosure relates to a device and method for coating thickness monitoring. The device comprises one or more lasers with different wavelengths, a light splitting optical element for beam splitting and beam combining of laser lights with different wavelengths, a diffuse plate, a driving motor, a lens, a multimode optical fiber, a light power meter, a test substrate and a coating fixture. The laser light is converted into partially coherent light through the rotating diffuse plate driven by a driving motor. The partially coherent light enters a multimode optical fiber through lens focusing, and is transmitted to a coating machine, collimated by a lens and then incident to a test substrate. The transmitted light enters a second multimode optical fiber after being focused by a lens, and is collimated and split at an optical fiber outlet. The light power meter is used for respectively measuring the power of the exiting light with different wavelengths and monitoring the transmissivities of lights with different wavelengths on the test substrate to realize the control of the coating thickness. The coating thickness monitoring device has the characteristics of simple structure, convenience in mounting, and narrow linewidth of the monitoring light source, and can realize the thickness control in a high-precision optical interference filter coating procedure.