Abstract: To provide a magnetron sputtering cathode, a magnetron sputtering apparatus, and a method of manufacturing a magnetic device, capable of generating a leakage magnetic field sufficiently large to form a magnetic tunnel necessary for discharge on the surface of a target even when the target is a magnetic body and thick and a ferromagnetic body is used as the target. The magnetron sputtering cathode of the present invention includes a target having a second annular groove provided on the sputtering surface of the target, a third annular projection provided on the non-sputtering surface of the target, a fourth annular groove provided outside the third annular projection on the non-sputtering surface, and a fourth annular projection provided outside the fourth annular groove on the non-sputtering surface. Further, the magnetron sputtering cathode includes a first magnet and a second magnet 6 having a polarity different from that of the first magnet on the non-sputtering surface side.

Abstract: A structure is provided in which a load lock chamber (51) for carrying in and out a wafer, a first conveyance module (53a) having a first conveyance mechanism (54a), a first process module (52a), a second conveyance module (53b) having a second conveyance mechanism (54b), and a second process module (52b) are sequentially connected in series. A wafer (55) is conveyed between the load lock chamber and the first process module by the first conveyance mechanism and conveyed between the first process module and the second process module by the second conveyance mechanism.

Abstract: The present invention provides a sputtering apparatus and a film forming method that can form a high quality film in a groove having a sloping wall such as a V-groove. The sputtering apparatus of the present invention includes a rotatable cathode (102), a rotatable stage (101), and a rotatable shield plate (105). The sputtering apparatus controls rotation of at least one of the cathode (102), the stage (101), and the shield plate (105) so that sputtering particles are incident on the V-groove formed in a substrate (104) at an angle of 50° or less with respect to a normal to a sloping wall of the V-groove.

Abstract: The present invention provides a sputtering apparatus and a film deposition method capable of forming a magnetic film with reduced variations in the direction of magnetic anisotropy. The sputtering apparatus of the present invention is provided with a rotatable cathode (802), a rotatable stage (801) and a rotatable shielding plate (805). The sputtering apparatus controls the rotation of at least one of the cathode (802), stage (801) and shielding plate (805) so that sputtered particles impinging at an angle formed with respect to a normal line of the substrate (804) of 0° or more and 50° or less out of sputtered particles generated from the target (803a) during sputtering are made to impinge on the substrate (804).

Abstract: To provide a sputtering apparatus that enables oblique film forming by arranging a target and a substrate so as to allow sputtered particles emitted from the target to obliquely enter the substrate selectively, and can form a magnetic film having high uniaxial magnetic anisotropy uniformly and compactly. A sputtering apparatus includes a cathode having a sputtering target supporting surface, the cathode being provided with a rotation axis about which the sputtering target supporting surface rotates, and a stage having a substrate supporting surface, the stage being provided with a rotation axis about which the substrate supporting surface rotates, and the sputtering apparatus is constituted such that the sputtering target supporting surface and the substrate supporting surface face to each other, and are rotatable independently about respective rotation axes.

Abstract: A sputtering apparatus includes a first target accommodating unit to accommodate a first target for film formation on a substrate; a first heater, arranged to surround the first target, for heating the substrate; and a second target accommodating unit arranged to surround the first heater to accommodate a second target for film formation on the substrate.

Abstract: The present invention provides a thin film formation apparatus which includes a plurality of chambers, and performs processing for forming thin films on two surfaces of a substrate transferred to the plurality of chambers, wherein a first sputtering chamber of the plurality of chambers includes a first sputtering film formation unit configured to perform a sputtering film formation process on a first surface of the substrate, and a first heating unit configured to heat a second surface opposite to the first surface of the substrate, and a second sputtering chamber of the plurality of chambers includes a second heating unit configured to heat the first surface of the substrate having undergone the sputtering film formation process performed by the first sputtering chamber, and a second sputtering film formation unit configured to perform a sputtering film formation process on the second surface of the substrate heated by the first sputtering chamber.

Abstract: A method for cleaning a substrate processing apparatus in which a first ion beam generator and a second ion beam generator are arranged opposite to each other to sandwich a plane on which a substrate is to be placed, and which processes two surfaces of the substrate, comprises steps of retreating the substrate from a position between the first ion beam generator and the second ion beam generator, and cleaning the second ion beam generator by emitting an ion beam from the first ion beam generator to the second ion beam generator.

Abstract: The magnet assembly includes one rotatable dipole magnet subassembly, which is formed from a permanent magnet and a magnetically permeable convex end portion coupled to each of both ends of the permanent magnet, and at least two magnetically permeable flux guide subassemblies, which are configured so as to be magnetically coupled to the dipole magnet subassembly. The flux guide subassembly has a concave end portion that fits into the convex end portion. The flux guide assemblies guide a flux from the dipole magnet subassembly and generate a flux outside. The condition of fitting into the flux guide subassemblies is reversed by rotating the dipole magnet subassembly, whereby it is possible to easily reverse the direction of a magnetic field generated outside.