Abstract: A sputter device for depositing a layer on a substrate in a vacuum chamber and having a layer property in each point of the substrate surface. The sputter device comprises at least one end block adapted for holding a cylindrical target having a longitudinal axis in a first direction, and a first drive means for providing a rotational movement of the at least one cylindrical target around its longitudinal axis. The sputter device includes a second drive means for applying a translational movement to an end block in a second direction. The first and the second drive means are adapted for, during sputtering, being simultaneously operational in the vacuum chamber. The movement of the first drive means does not impact the uniformity of the layer sputtered on the substrate in the direction on the surface of the substrate corresponding to a perpendicular projection of the second direction onto the substrate.

Abstract: A device for use in a sputter system, comprising at least a first end block and a second end block positioned at opposite sides of the sputter system. The device is adapted such that a target assembly comprising at least one target tube or sputter magnetron, when mounted on the first and second end blocks, may be powered actively with RF power at both sides of the assembly, and such that the target assembly, when mounted, is not actively powered continuously with RF power simultaneously at both extremities of a target tube or sputter magnetron. An assembly comprising said device and a control unit for controlling powering of opposite sides of the target assembly by RF power such that the target assembly, when mounted, is not actively powered continuously with RF power simultaneously at both extremities of a target tube or sputter magnetron.

Abstract: An end-block for rotatably carrying a sputtering target tube and for rotatably restraining a magnet bar inside the sputtering target tube includes a receptacle for receiving a magnet bar fitting. The receptacle comprises a first part of a signal connector arranged to receive a second part of a signal connector from the magnet bar fitting, and allow a signal connector between the end-block and the magnet bar to be formed. The end-block is adapted for providing protection means to the signal connector for protecting it from degradation, destruction or interference of a power and/or data signal transmitted between the end-block and the magnet bar, due to surrounding cooling fluid and/or surrounding high energy fields. The disclosure provides a corresponding magnet bar, and a method for adjusting a magnetic configuration of a magnet bar in a cylindrical sputtering apparatus.

Abstract: A sputtering target having a one-piece top coat comprising a mixture of oxides of zinc, tin, and optionally gallium, characterized in that said one-piece top coat has a length of at least 80 cm; a method for forming such a sputtering target and the use of such a target for forming films.

Abstract: A sputtering method and apparatus having at least one set of dual rotatable cylindrical sputtering targets mounted in a vacuum chamber. Magnet assemblies in hollow target cylinders provide erosion zones running long the parallel sides of a racetrack that act as target flux sources towards a substrate. These parallel erosion zones have a highly concentrated plasma density for rapid sputtering of the target and any reactive material. Features include the angular distance between normals to adjacent parallel erosion zones, the angle greater than 45° subtended at the center of the cylindrical target, placement of the substrate with respect to the targets, and pointing angles (orientation or tilt) of the racetracks toward the substrate and/or each other. These parameters form a relatively wide and efficient constant flux deposition region at the substrate, and allows for high deposition rates at constant reactive gas partial pressures with substantially uniform film stoichiometry and thickness.

Abstract: An end-block for use in a tubular magnetron sputtering apparatus is disclosed. Such an end-block rotatably transfers movement, coolant 5 and electrical current to the target while maintaining vacuum integrity and a closed coolant circuit. It hence comprises a drive means, a rotary electrical contact means, a bearing means, a number of rotary coolant seal means and a number of vacuum seal means. The inventive end-block occupies a minimal axial length along the target thus allowing 10 space savings in existing equipment such as e.g. display coaters. The axial length is reduced by mounting at least two of the means radial to one another.

Abstract: A sputtering method and apparatus having at least one set of dual rotatable cylindrical sputtering targets mounted in a vacuum chamber. Magnet assemblies in hollow target cylinders provide erosion zones running long the parallel sides of a racetrack that act as target flux sources towards a substrate. These parallel erosion zones have a highly concentrated plasma density for rapid sputtering of the target and any reactive material. Features include the angular distance between normals to adjacent parallel erosion zones, the angle greater than 45° subtended at the center of the cylindrical target, placement of the substrate with respect to the targets, and pointing angles (orientation or tilt) of the racetracks toward the substrate and/or each other. These parameters form a relatively wide and efficient constant flux deposition region at the substrate, and allows for high deposition rates at constant reactive gas partial pressures with substantially uniform film stoichiometry and thickness.

Abstract: A sputtering magnetron (300) insertable in a rotatable target is described. The magnetron is designed around a single piece, multiwalled tube (102, 202) with compartments (316, 316?, 318, 318?) extending over the length of the tube. The multiwalled tube gives a much stiffer magnetron carrier structure compared to prior art magnetrons. As a result, the magnetic field generator can be mounted inside a compartment and the distance between magnets and target surface is easily adjustable as the tube is much stiffer than the generator. Additionally, the coolant channels can be incorporated inside the tube and close to the outer wall of the tube so that coolant can be supplied in the vicinity of the magnetic field generator. The increased stiffness of the magnetron allows the target tube to be carried by the magnetron—not the other way around—at least during part of the useful life of the target.