Abstract: Disclosed is a substrate processing apparatus including first and second chambers stacked one above the other; a first opening that is provided in a wall of the first chamber that faces the second chamber, and that allows a substrate to pass through the first opening; a second opening that is provided in a wall of the second chamber that is in communication with the first opening and that allows the substrate to pass through the second opening; an opening and closing member that is provided inside the first chamber so as to move up and down and that opens and closes the first opening; a substrate mounting member that is provided closer to the second chamber than the opening and closing member, and that moves the substrate between the first and second chambers; and a substrate processing member provided in the second chamber.

Abstract: The present invention provides a magnet unit and a magnetron sputtering apparatus which can suppress the consumption amount of a target by efficiently consuming the target and can easily cause erosion on the target to progress uniformly regardless whether the target size is small or large and whether the target is made of magnetic material or not.

Abstract: A method and an apparatus for manufacturing a perpendicular magnetic recording medium are provided which can easily demagnetize a magnetic layer with a high coercivity. The method includes: forming a magnetic layer on a substrate; applying magnetic fields parallel to the surface of the magnetic layer having a coercivity reduced below the intensity of said magnetic field by heating of the magnetic layer; and removing said magnetic field.

Abstract: A sputtering apparatus is provided with an elongated target holder, a substrate holder having a substrate receiving surface, and a mask assembly having an opening configured between the target holder and the substrate holder. The mask assembly is comprised of a first and second masking part having facing edges that form the opening and are disposed parallel to the substrate receiving surface and independently movable in a direction perpendicular to the length of the target holder and parallel to the substrate receiving surface, or in a direction perpendicular to the substrate receiving surface.

Abstract: An ion beam generator includes a discharge tank for generating plasma that includes ions. A lead-out electrode has an annular grid portion provided with openings for leading out the ions generated in the discharge tank, while accelerating the generated ions as an annular ion beam. A deflecting electrode deflects the annular ion beam, which is led out of the lead-out electrode, in an annular center direction.

Abstract: The present invention is directed to align crystal c-axes in magnetic layers near two opposed junction wall surfaces of a magnetoresistive element so as to be almost perpendicular to the junction wall surfaces. A magnetic sensor stack body has, on sides of opposed junction wall surfaces of a magnetoresistive element, field regions for applying a bias magnetic field to the element. The field region has first and second magnetic layers having magnetic particles having crystal c-axes, the first magnetic layer is disposed adjacent to the junction wall surface in the field region, the crystal c-axes in the first magnetic layer are aligned and oriented along an ABS in a film plane, the second magnetic layer is disposed adjacent to the first magnetic layer in the field region, and the crystal c-axis directions in the second magnetic layer are distributed at random in a plane.

Abstract: [Objection of the invention]An ion beam generator, a thermal distortion in a grid assembly is reduced. [Structure to solve the objection]Thermal expansion coefficients ?P, ?M and ?G, for a sidewall (1A) of a discharge chamber, mounting platform (40) and extraction grid electrode assembly (20) are selected to have a relation: ?P>?M??G. For example, the material of discharge chamber sidewall is stainless steel o aluminum, the material of grids is Mo, W or C and the material of platform is Ti or Mo.

Abstract: A perpendicular recording medium having a perpendicular magnetic recording layer and a magnetically soft underlayer structure disposed beneath the recording layer. The soft underlayer structure includes at least first and second soft magnetic layers having different magnetic permeabilities to create a magnetic permeability gradient in the soft underlayer structure. One or more of the soft magnetic layers can be antiparallel coupled. The soft underlayer structure of the present invention having a magnetic permeability gradient advantageously leads to reduced adjacent track erasure (ATE) while maintaining good overwrite (OW) properties.

Abstract: A perpendicular recording medium having a perpendicular magnetic recording layer and a magnetically soft underlayer structure disposed beneath the recording layer. The soft underlayer structure includes at least first and second soft magnetic layers having different magnetic permeabilities to create a magnetic permeability gradient in the soft underlayer structure. One or more of the soft magnetic layers can be anti-parallel coupled. The soft underlayer structure of the present invention having a magnetic permeability gradient advantageously leads to reduced adjacent track erasure (ATE) while maintaining good overwrite (OW) properties.

Abstract: A substrate cooling device includes: a substrate holding stage including a recess defining a space between a substrate mounting unit and a substrate mounted on the substrate mounting unit; a holding member that exerts a pressing force against the substrate holding stage so as to fix the substrate to the substrate holding stage; a refrigerator connected to the substrate holding stage; a coolant gas inlet path including a coolant gas inlet opening that is provided at the substrate holding stage and opens to a recessed face of the recess, the coolant gas inlet path connecting a space in the recess via the coolant gas inlet opening to a coolant gas supply; and a coolant gas outlet path including a coolant gas outlet opening that is provided at the substrate holding stage independently of the coolant gas inlet opening and opens to the recessed face of the recess.

Abstract: A magnet unit has a first magnet element and a second magnet element. The first magnet element includes a first magnet which is provided to stand upright on a yoke plate, a second magnet which is provided to stand upright on the yoke plate and has a magnetic pole unlike the first magnet, and a third magnet which is provided with a tilt between the first magnet and the second magnet. The second magnet element includes a fourth magnet which is provided to stand upright on the yoke plate, a fifth magnet which is arranged to stand upright on the yoke plate and has a magnetic pole unlike the fourth magnet, and a sixth magnet which is provided with a tilt between the fourth magnet and the fifth magnet. The first magnet element and the second magnet element are alternately arranged in an endless shape.

Abstract: A method of processing a substrate in an apparatus including a substrate holder which holds the substrate, an ion source which emits an ion beam, a neutralizer which emits electrons, and a shutter which is arranged between a space in which the ion source and the neutralizer are arranged and a space in which the substrate holder is arranged, and configured to shield the ion beam traveling toward the substrate, includes adjusting an amount of electrons which are emitted by the neutralizer and reach the substrate holder during movement of the shutter.

Abstract: There is provided an ion beam generating apparatus capable of reducing power consumption and obtain highly-accurate uniformity in a substrate process without providing a mechanism to rotate a substrate. Each of ion beam generating apparatuses 1a and 1b includes a discharging tank for generating plasma, an extraction electrode including an inclined portion arranged so as to be inclined with respect to an irradiated surface for extracting an ion generated in the discharging tank, a rotating driving unit 30 provided out of the discharging tank for rotating the extraction electrode, and a rotation supporting member 31 for coupling the rotating driving unit 30 and the extraction electrode 7, wherein an insulator block 34 arranged around the rotation supporting member 31 is included in the discharging tank.

Abstract: The present invention is directed to align crystal c-axes in magnetic layers near two opposed junction wall surfaces of a magnetoresistive element so as to be almost perpendicular to the junction wall surfaces. A magnetic sensor stack body has, on sides of opposed junction wall surfaces of a magnetoresistive element, field regions for applying a bias magnetic field to the element. The field region has first and second magnetic layers having magnetic particles having crystal c-axes, the first magnetic layer is disposed adjacent to the junction wall surface in the field region, the crystal c-axes in the first magnetic layer are aligned and oriented along an ABS in a film plane, the second magnetic layer is disposed adjacent to the first magnetic layer in the field region, and the crystal c-axis directions in the second magnetic layer are distributed at random in a plane.

Abstract: Perpendicular magnetic recording media having a magnetic capping layer that is exchange coupled to an underlying perpendicular magnetic recording layer. The magnetic coupling layer is a granular layer having a high saturation magnetization (Ms). The perpendicular magnetic recording layer can include magnetic grains separated by an oxide grain boundary phase.

Abstract: There are comprised a load chamber (51) for carrying in a wafer from outside, an unload chamber (53) for carrying out a wafer to outside, and a plurality of conveyance chambers (54a, 54b, 54c) and a plurality of process modules (52a, 52b) connected in series between the load chamber and the unload chamber. The conveyance chambers and the process modules are connected alternately and the plurality of conveyance chambers includes a first end conveyance chamber (54a) connected to the load chamber, a second end conveyance chamber (54c) connected to the unload chamber, and another one or a plurality of intermediate conveyance chambers (54b).

Abstract: The present invention provides a magnet unit and a magnetron sputtering apparatus which can suppress the consumption amount of a target by efficiently consuming the target and can easily cause erosion on the target to progress uniformly regardless whether the target size is small or large and whether the target is made of magnetic material or not.

Abstract: The present invention provides a sputtering apparatus and a film-forming method capable of forming a magnetic film having a reduced variation in the orientation of the magnetic anisotropy. The sputtering apparatus of the present invention is equipped with a rotatable cathode and a rotatable stage. The stage can have an electrostatic chuck. Moreover, the stage may electrically be connected with a bias power source capable of applying a bias voltage to the stage. Furthermore, the stage may have the electrostatic chuck and electrically be connected with the bias power source.

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: A magnet unit, which can realize uniform film thickness distribution of a thin film formed on a substrate without increasing the length and width of a target. The magnet unit includes a peripheral magnet, which is disposed on the yoke on the back side of a cathode electrode so as to follow the outline of a target, and an inner magnet disposed in the peripheral magnet and having a polarity different from the polarity of the peripheral magnet. The magnet unit provides a magnetic track MT that is a set of regions which tangents of magnetic field lines M generated on the target parallels to the target surface. The magnet unit further includes n (n is a positive integer of two or more) extending magnetic pole portions and n?1 projecting magnetic pole portions, which form 2n?1 folded shape portions U at the both ends in the longitudinal direction of the magnetic track.