It is provided a magnetron-sputtering coating system including a sputtering chamber. The sputtering chamber therein includes: a set of target, formed by concatenating a plurality pieces of target; a substrate carrier, arranged to be opposite to the target set, and support a substrate to be coated with a film; and a driving device, arranged to drive the substrate carrier to reciprocate in a direction of the arrangement of the target.

A circular PVD chamber has a plurality of sputtering targets mounted on a top wall of the chamber. A pallet in the chamber is coupled to a motor for rotating the pallet about its center axis. The pallet has a diameter less than the diameter of the circular chamber. The pallet is also shiftable in an XY direction to move the center of the pallet beneath any of the targets so all areas of a workpiece supported by the pallet can be positioned directly below any one of the targets. A scanning magnet is in back of each target and is moved, via a programmed controller, to only be above portions of the workpiece so that no sputtered material is wasted. For depositing a material onto small workpieces, a cooling backside gas volume is created between the pallet and the underside of sticky tape supporting the workpieces.

A circular PVD chamber has a plurality of sputtering targets mounted on a top wall of the chamber. A pallet in the chamber is coupled to a motor for rotating the pallet about its center axis. The pallet has a diameter less than the diameter of the circular chamber. The pallet is also shiftable in an XY direction to move the center of the pallet beneath any of the targets so all areas of a workpiece supported by the pallet can be positioned directly below any one of the targets. A scanning magnet is in back of each target and is moved, via a programmed controller, to only be above portions of the workpiece so that no sputtered material is wasted. For depositing a material onto small workpieces, a cooling backside gas volume is created between the pallet and the underside of sticky tape supporting the workpieces.

A sputtering apparatus includes a process chamber in which a sputtering process is performed, a substrate holder provided in the process chamber and fixing a horizontal position of a substrate during the sputtering process, and a first sputter gun provided to be vertically spaced apart from the substrate in the process chamber. The first sputter gun is spaced apart from the substrate by a first horizontal distance during the sputtering process. The first sputter gun is fixed during the sputtering process. The first horizontal distance is a horizontal distance between the substrate and the first sputter gun when viewed from a plan view.

What is specified is a method for producing a coating comprising the following steps: providing a material source having a top surface and a main coating direction, providing a substrate holder having a top surface, providing at least one base layer, having a coating surface remote from the substrate holder, on the top surface of the substrate, attaching the substrate holder to a rotating arm, which has a length along a main direction of extent of the rotating arm, setting the length of the rotating arm in such a manner that a normal angle () throughout the method is at least 30 and at most 75, applying at least one coating to that side of the base layer which has the coating surface by means of the material source, whereinduring the coating process with the coating, the substrate holder is rotated about a substrate axis of rotation running along the main direction of extent of the rotating arm.

A drum sputtering device that can uniformly deposit target atoms on all over particles is provided. The drum sputtering device includes a vacuum container 2 that contains particles, a tubular drum 10 that is arranged inside the vacuum container 2 and at least one end face 10c of which is open, and a sputtering target 16 that is arranged inside the drum 10. With a supporting arm 11, a drive motor 12 for rotation, a drive motor 13 for swing, a first gear member 14, and a second gear member 15, the drum can be rotated around the axis of the drum 10 and the drum 10 can be swung so that one end portion 10e and the other end portion 10f in the axial direction of the drum 10 are relatively vertically switched.

A method of manufacturing a pressure sensor comprises: above a film portion formed on one surface of a substrate, depositing a first magnetic layer, a second magnetic layer and an intermediate layer between the first and second magnetic layers on one surface of a substrate; removing the deposited layers leaving a part thereof; and removing a part of the substrate from another surface of the substrate. By removing the deposited layers leaving apart thereof, a strain detecting element is formed in a part of a first region, the strain detecting element comprising the first magnetic layer, the second magnetic layer and the intermediate layer. By removing a part of the substrate, a part of the first region of the substrate is removed. In addition, the deposition of the first magnetic layer is performed with the substrate being bended.

A method of manufacturing a pressure sensor comprises: above a film portion formed on one surface of a substrate, depositing a first magnetic layer, a second magnetic layer and an intermediate layer between the first and second magnetic layers on one surface of a substrate; removing the deposited layers leaving a part thereof; and removing a part of the substrate from another surface of the substrate. By removing the deposited layers leaving apart thereof, a strain detecting element is formed in a part of a first region, the strain detecting element comprising the first magnetic layer, the second magnetic layer and the intermediate layer. By removing a part of the substrate, a part of the first region of the substrate is removed. In addition, the deposition of the first magnetic layer is performed with the substrate being bended.

Implementations described herein generally relate to metal oxide deposition in a processing chamber. More specifically, implementations disclosed herein relate to a combined chemical vapor deposition and physical vapor deposition chamber. Utilizing a single oxide metal deposition chamber capable of performing both CVD and PVD advantageously reduces the cost of uniform semiconductor processing. Additionally, the single oxide metal deposition system reduces the time necessary to deposit semiconductor substrates and reduces the foot print required to process semiconductor substrates. In one implementation, the processing chamber includes a gas distribution plate disposed in a chamber body, one or more metal targets disposed in the chamber body, and a substrate support disposed below the gas distribution plate and the one or more targets.

Disclosed is a substrate processing system which enables combined static and pass-by processing. Also, a system architecture is provided, which reduces footprint size. The system is constructed such that the substrates are processed therein vertically, and each chamber has a processing source attached to one sidewall thereof, wherein the other sidewall backs to a complementary processing chamber. The chamber system can be milled from a single block of metal, e.g., aluminum, wherein the block is milled from both sides, such that a wall remains and separates each two complementary processing chambers.