Abstract: The present invention has an objective to provide a processing method and an ion beam processing apparatus capable of inhibiting deposition of redeposited films even for fine patterns. In an embodiment of the present invention, ion beam processing is performed such that an etching amount of an ion beam incident in extending directions of pattern trenches formed on a substrate is made larger than the etching amount of the ion beam incident in other directions. This processing enables fine patterns to be processed while inhibiting redeposited films from being deposited on the bottom portions of the trenches of the fine patterns.

Abstract: An X-ray generating device includes an X-ray tube, an X-ray tube drive circuit, an electron acceleration voltage generation circuit, and a control unit communicating with the drive circuit and the voltage generation circuit, the X-ray tube, the drive circuit, and the voltage generation circuit are arranged inside a storage container filled with an insulating oil, a path connecting the drive circuit and the control unit includes an optical fiber cable arranged inside the storage container, the optical fiber cable has a coating that suppresses fluctuation due to a convective flow of the insulating oil, the coating is cured by, from a resin material containing a plasticizer, a part of the plasticizer being leaching out, and the control unit is configured to facilitate leaching of the plasticizer by driving the voltage generation circuit to apply a voltage to the optical fiber cable in a state of no X-ray being generated.

Abstract: A sputtering apparatus includes a shutter arranged having a first surface on a side of a substrate holder and a second surface on the opposite side, a first shield having a third surface including a portion facing the second surface and a fourth surface on the opposite side, a second shield having a fifth surface including a portion facing end portions of the shutter and the first shield, and a gas supply unit supplying a gas into a space arranged outside the first shield to communicate with a first gap between the second surface of the shutter and the third surface of the first shield. The second shield includes a protruding portion on the fifth surface to form a second gap between the protruding portion and the end portion of the shutter.

Abstract: To provide an ion beam etching method which enables a highly uniform IBE process even under a low-angle-incident static condition, without increase in the size of an apparatus. The ion beam etching method includes: changing a position of an opening portion with respect to a substrate; etching the substrate with an ion beam passing through the opening portion; and reducing a tilt angle as a center of a site where the ion beam is incident on the substrate moves away from the ion source.

Abstract: The present invention provides a means capable of determining the surface state of the target to execute accurate and quick cleaning of necessary part. The means includes: a magnet unit capable of forming a magnetic field on the surface of a target; a rotary system capable of driving the magnet unit to change the magnetic field pattern; and an ammeter configured to measure target current when the magnetic field is formed by the magnet unit and discharge voltage is applied to a target electrode to which the target is attached. The position of the magnet unit is variously changed by the rotary system, and the target current is measured at each position and compared with a reference value. It is then determined whether cleaning is necessary at each position, so that cleaning can be performed only for necessary part.

Abstract: An embodiment of the present invention is a method of manufacturing a perpendicular MTJ device which includes: a first stacked structure including a pair of CoFeB layers sandwiching an MgO layer; and a second stacked structure including a multilayer, the method comprising the steps of: forming one of the first and second stacked structures on a substrate; inspecting a property of the substrate with the one of the first and second stacked structures formed thereon while exposing the substrate to the atmosphere; and forming another one of the first and second stacked structures on the substrate with the one of the first and second stacked structures formed thereon.

Abstract: A heating apparatus includes a heater, an electron reflection plate, a filament arranged between the heater and the electron reflection plate, a heating power supply configured to supply an AC voltage between a first terminal and a second terminal of the filament to emit thermoelectrons from the filament, an acceleration power supply configured to supply an acceleration voltage between the filament and the heater, and a resistor arranged so as to form a path which connects the electron reflection plate and the heating power supply.

Abstract: A vacuum arc deposition apparatus for forming a ta-C film on a substrate using arc discharge includes a holding unit that holds a target unit, an anode unit into which electrons emitted from the target unit flow, and a power supply that supplies, between the target unit and the anode unit, a current for generating a plasma by arc discharge. The current supplied by the power supply at the time of the arc discharge is generated by superimposing, on a DC current, a pulse current of a pulse frequency not higher than 140 Hz.

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 sputtering apparatus includes a vacuum chamber, a substrate holder, a target support member, a cathode magnet arranged on a side of the target support member, which is opposite to a side of a substrate held by the substrate holder, a magnet moving unit configured to adjust a distance between the cathode magnet and the target support member, a target moving unit configured to adjust a distance between the target support member and the substrate, and a control unit configured to control the target moving unit and the magnet moving unit.

Abstract: An oxidation process apparatus according to one embodiment of the present invention includes: a substrate holder provided in a processing chamber and having a substrate holding surface; a gas introduction unit for introducing an oxygen gas; a cylindrical member; and a substrate holder drive unit for changing relative positions of the substrate holder and the cylindrical member to allow the substrate holding surface and the cylindrical member to form an oxidation process space. The cylindrical member is provided so as to form a gap between the cylindrical member and the substrate holder during formation of the space. The oxygen gas is introduced restrictively into the space. The oxygen gas introduced from the gas introduction unit is evacuated through the gap.

Abstract: A reactive sputtering apparatus includes a chamber, a substrate holder provided in the chamber, a target holder which is provided in the chamber and configured to hold a target, a deposition shield plate which is provided in the chamber so as to form a sputtering space between the target holder and the substrate holder, and prevents a sputter particle from adhering to an inner wall of the chamber, a reactive gas introduction pipe configured to introduce a reactive gas into the sputtering space, an inert gas introduction port which introduces an inert gas into a space that falls outside the sputtering space and within the chamber, and a shielding member which prevents a sputter particle from the target mounted on the target holder from adhering to an introduction port of the reactive gas introduction pipe upon sputtering.

Abstract: A deposition apparatus comprises a source unit configured to generate a plasma by arc discharge, a deposition unit in which a deposition target material is arranged so as to be irradiated with the plasma generated in the source unit, and an induction unit configured to induce the plasma for the source unit to the deposition unit. The induction unit comprises a partition unit airtightly connected to each of the source unit and the deposition unit and configured to pass the plasma inside, and a plurality of magnet units configured to form a magnetic field to induce the plasma in the partition unit. The plurality of magnet units are connected to adjust a connection angle, and the partition unit includes a tubular member bendable according to the connection angle of the plurality of magnet units.

Abstract: The purpose of the present invention is to prevent a drop in secondary electron emission characteristics due to the inside wall of a chamber being covered by a noble metal film continuously formed by plasma sputtering, and so generate and maintain the plasma. After a noble metal film is formed on a given substrate and before a film is formed on a subsequent substrate, a secondary electron emission film comprising a material having a secondary electron emission coefficient higher than that of the noble metal is formed on the inner wall of the chamber.

Abstract: Provided is a method for manufacturing a magnetoresistive element, including a step of forming a tunnel barrier layer, wherein the step of forming the tunnel barrier layer includes a deposition step of depositing a metal film on top of a substrate, and an oxidation step of subjecting the metal film to an oxidation process. The oxidation step includes holding the substrate having Mg formed thereon, on a substrate holder in a processing container in which the oxidation process is performed, supplying an oxygen gas to the substrate by introducing the oxygen gas into the processing container, at a temperature at which Mg does not sublime, and heating the substrate after the introduction of the oxygen gas.

Abstract: A magnetoresistance effect element of the present invention includes: a barrier layer; a reference layer formed on one surface of the barrier layer; a free layer formed on the other surface of the barrier layer; and a pinned layer placed on the opposite side of the reference layer from the barrier layer. The pinned layer includes a structure obtained by stacking Ni, Co, Pt, Co, Ru, Co, Pt, Co, and Ni layers in this order.

Abstract: An ion beam etching method includes applying a positive voltage for extracting ions into a vacuum container to a first electrode, under a first condition where irradiation of a substrate with an ion beam is blocked off by a shutter, generating plasma in an internal space under the first condition, forming the ion beam by forming, under the first condition, a second condition where a positive voltage is applied to the first electrode and a negative voltage is applied to a second electrode, and moving the shutter and processing the substrate by irradiating the substrate with the ion beam.

Abstract: The present invention provides a vacuum processing apparatus capable of reducing attachment of particles generated in a processing space to an inner wall of a chamber, and of easily adjusting pressure in the processing space while introducing a gas into the processing space at a desired flow rate. A vacuum processing apparatus according to one embodiment includes: a container; a gas exhaust portion; a substrate holder configured to retain a substrate; a shield provided to surround the substrate holder and dividing an inside of the container into a processing space and an outside space; a gas introducing portion; a plasma generating portion; and an exhaust portion provided to the shield having a communication path through which the processing space and the outside space communicate, wherein at least part of the communication path is hidden from a region where the plasma generating portion generates the plasma.

Abstract: An ion beam etching device includes a grid provided between a treatment chamber and a plasma generation chamber, and for forming an ion beam by drawing ions from the plasma generation chamber; a gas introduction unit for introducing discharge gas into the plasma generation chamber; an exhaust for exhausting the treatment chamber; a substrate holder; a control unit to receive a measurement result of an in-plane film thickness distribution before the substrate is processed; and an electromagnetic coil provided outside of the plasma generation chamber in a ceiling portion opposite to the grid of the plasma generation chamber. The electromagnetic coil includes an outer coil provided on an outer circumference of the ceiling portion and an inner coil provided on an inner circumference of the ceiling portion, and the control unit controls the currents applied to the outer coil and the inner coil in accordance with the measurement result.

Abstract: A power supply device supplies power to a substrate holder having a plurality of electrodes. The device includes a first fixed conductive member, a second fixed conductive member, a fixed insulating member fixed to an insulating housing portion and configured to insulate the first fixed conductive member from the second fixed conductive member, a first rotation conductive member, a second rotation conductive member, a rotation insulating member fixed to an insulating column portion and configured to insulate the first rotation conductive member from the second rotation conductive member, a first power supply member configured to supply a first voltage to the substrate holder via the first rotation conductive member and the first fixed conductive member, and a second power supply member configured to supply a second voltage to the substrate holder via the second rotation conductive member and the second fixed conductive member.