Abstract: Provided is a film formation apparatus with which an anti-fouling film having high usability and antiwear performance may be formed efficiently. According to a film formation apparatus (1) of the present invention, a substrate holder (12) which comprises a basal body holding surface for folding a plurality of substrates (14) is disposed in a vacuum container (10) in a rotatable manner.

Abstract: An optical film thickness measuring device, enabling direct measurement of a film thickness of a product in real time accurately without a monitor substrate, includes: a projector, a light receiver, inner beam splitters disposed in a base substrate holder to reflect a measurement beam to a base substrate, an inner optical reflector that totally reflects a measurement beam from the closest inner beam splitter, external beam splitters the measurement beam from the inner beam splitters toward the light receiver, and an outer optical reflector that reflects the measurement beam from the optical reflector toward the light receiver. The measurement beam reflected by the inner beam splitters and the inner optical reflector is passed through the base substrate and then reflected by the external beam splitters and the outer optical reflector to be guided to the light receiver, so that the measurement beam is received by the light receiver.

Abstract: An optical film thickness meter capable of measuring an optical film thickness and spectroscopic characteristics highly accurately, and a thin film forming apparatus with the optical film thickness meter are provided. The optical film thickness meter includes a light projector, a light receiver, a monochromator, and a reflection mirror having a reflection surface substantially perpendicularly to the optical axis of measurement light on the side opposite to an actual substrate. The actual substrate is disposed having a predetermined angle to the optical axis. The measurement light passes through the actual substrate twice, whereby a change in transmissivity can be increased, and control accuracy of thickness measurement is improved. Measurement errors caused by a difference in transmission positions is prevented.

Abstract: A magnetic field generator arranged behind a target and for generating a magnetic field on a front surface of the target based on magnetic force lines can include a ring-shaped outer magnetic body having a pole axis in a parallel direction (X-direction) with respect to the target surface, a center magnetic body arranged on an inner side of the outer magnetic body and having a pole axis in a parallel direction (X-direction) with the direction of the pole axis of the outer magnetic body, a yoke plate for supporting the outer magnetic body and the center magnetic body from behind, and a magnetic permeable plate for changing a magnetic field distribution of the front surface of the target. The magnetic permeable plate is arranged so as to be supported by the yoke plate from behind.

Abstract: A thin film formation method is provided, by which needless film formation due to trial film formation is omitted and film formation efficiency can be improved. This invention is a method for sputtering targets to form a film A having an intended film thickness of T1 as the first thin film on a substrate and monitor substrate held and rotated by a rotation drum and, subsequently, furthermore sputtering the targets used in forming the film A to form a film C having an intended film thickness of T3 as the second thin film, which is another thin film having the same composition as the film A; comprising film thickness monitoring steps S4 and S5, a stopping step S7, an actual time acquisition step S8, an actual rate calculating step S9 and a necessary time calculating step S24.

Abstract: Provided is a thin film forming apparatus for reducing operation time and cost by forming a film only on a specific portion on substrates. A substrate holding mechanism provided in the apparatus includes: substrate holding members holding substrates in a manner that a part of a non-film forming portion of a substrate overlaps the other substrate and a film forming portion is exposed, a support member supporting the substrate holding members, and a rotation member which rotates the support member. The substrate holding members include: holding surfaces holding the substrates and disposed between a film forming source and the substrates, step portions formed between the holding surfaces in a manner that ends of the substrates respectively contact with the step portions, and opening portions formed on the holding surfaces of the portion corresponding to the film forming portion when the ends of the substrates contact with the step portions.

Abstract: An optical film thickness meter capable of measurement of an optical film thickness and spectroscopic characteristics with high accuracy and a thin film forming apparatus provided with the optical film thickness meter are provided. The optical film thickness meter includes a light projector (11), a reflection mirror (17), a light receiver (19), and a monochromator (20), and the reflection mirror (17) has a reflection surface disposed substantially perpendicularly to the optical axis of measurement light on the side opposite to an actual substrate (S) with respect to an incident direction of the measurement light. Also, the actual substrate (9) is disposed having a predetermined inclination angle (?) with respect to the optical axis of the measurement light. The measurement light (outgoing light and reflection light) passes through the actual substrate (S) twice, whereby a change amount in transmissivity (light amount) can be increased, and control accuracy of film thickness measurement can be improved.

Abstract: A method of vapor depositing a vapor deposition substance onto substrates within a vacuum vessel includes holding the substrates with a dome shaped holder disposed within the vacuum vessel, rotating the dome shaped holder, vapor depositing a substance from a vapor deposition source disposed oppositely to the substrates, supplying ions from an ion source to the substrates, and supplying neutralizing electrons from a neutralizer to the substrates.

Abstract: [Object]To provide a manufacturing method of an optical filter having favorable film quality by removing a foreign substance adhered onto a surface of a substrate by cleaning before a thin film is formed. [Solution] By performing a cleaning step P1 for cleaning a substrate S by means of a solution including water, a pre-treatment step P3 for plasma-treating a surface of the substrate S cleaned in the cleaning step P1 by plasma of an oxygen gas, and a thin film formation step (P4, P5) for forming the thin film on the surface of the substrate S plasma-treated in the pre-treatment step P3, the foreign substance adhered onto the surface of the substrate can be effectively removed. In the pre-treatment step P3, only the oxygen gas is introduced to an area where the plasma is generated, and a flow rate of the oxygen gas to be introduced is greater than a flow rate of the oxygen gas introduced in the thin film formation step.

Abstract: An optical thin-film vapor deposition apparatus and method are capable of producing an optical thin-film by vapor depositing a vapor deposition substance onto substrates (14) within a vacuum vessel (10). A dome shaped holder (12) is disposed within the vacuum vessel (10) and holds the substrates (14). A drive rotates the dome shaped holder (12). A vapor depositing source (34) is disposed oppositely to the substrates (14). An ion source (38) irradiates ions to the substrates (14). A neutralizer (40) irradiates electrons to the substrates (14). The ion source (38) is disposed at an angle between an axis, along which ions are irradiated from the ion source (38), and a line perpendicular to a surface of each of the substrates (14). The angle is between 8° inclusive and 40° inclusive. A ratio of a distance in a vertical direction between (i) a center of rotational axis of the dome shaped holder (12), and (ii) a center of the ion source (38), relative to a diameter of the dome shaped holder (12), is between 0.

Abstract: The method for depositing a film of the present invention comprises the first irradiation step of irradiating particles having energy on a surface of a substrate 101, the first film deposition step of depositing a first film 103 on the surface of the substrate 101 subjected to the first irradiation step by using a dry process, and the second film deposition step of depositing a second film 105 having oil repellency on a surface of the first film 103. According to the present invention, a method for depositing a film enabling production of an oil-repellent substrate comprising an oil-repellent film having abrasion resistance of a practically sufficient level can be provided.

Abstract: The method for depositing a film of the present invention comprises the first film deposition step of depositing a first film 103 having hardness higher than hardness of a substrate 101 on a surface of the substrate 101, the first irradiation step of irradiating particles having energy on the first film 103, and the second film deposition step of depositing an oil-repellent film 105 on a surface of the first film 103 subjected to the first irradiation step. According to the present invention, a method for depositing a film enabling production of an oil-repellent substrate comprising an oil-repellent film having abrasion resistance of a practically sufficient level can be provided.

Abstract: [Object] To provide a deposition apparatus 1 capable of suppressing a temporal change in film formation conditions. [Solution] In the deposition apparatus 1 including a substrate holder 12 supported in a vacuum chamber 10 grounded on the earth, a substrate 14 held by the substrate holder 12, deposition sources 34, 36 placed distant from the substrate 14 so as to face the substrate, an ion gun 38 for irradiating ions to the substrate 14, and a neutralizer 40 for irradiating electrons to the substrate 14, an irradiated ion guide member 50 and an irradiated electron guide member 52 are respectively attached to the ion gun 38 and the neutralizer 40.

Abstract: [Object] To provide a bias sputtering device having a self-revolving mechanism capable of reducing generation of foreign substances adhered to film formation surfaces. [Solution] In a bias sputtering device 1 provided with a substrate holder 12 having a self-revolving mechanism, the substrate holder 12 has a revolving member 21 and turning holders 23, and on the side of back surfaces of substrates 14 respectively attached to the turning holders 23, disc shaped substrate electrodes 30 having the same size as the substrates 14 are provided at positions distant from the substrates 14 by 0.5 to 10 mm.

Abstract: [Object] To provide a deposition apparatus 1 capable of suppressing a temporal change in film formation conditions. [Solution] In the deposition apparatus 1 including a substrate holder 12 supported in a vacuum chamber 10 grounded on the earth, a substrate 14 held by the substrate holder 12, deposition sources 34, 36 placed distant from the substrate 14 so as to face the substrate, an ion gun 38 for irradiating ions to the substrate 14, and a neutralizer 40 for irradiating electrons to the substrate 14, the vacuum chamber 10 is provided with an inner wall 30 electrically floating, and the neutralizer 40 is arranged on the inner side surface side of the vacuum chamber 10 so as to be distant from the ion gun 38.

Abstract: A thin-film forming apparatus is provided capable of forming a thin-film by bringing ions of some degree in plasma into contact with the thin-film. This thin-film forming apparatus comprises a plasma generator disposed at a position corresponding to an opening of a vacuum chamber for producing plasma in the vacuum chamber, a base plate holder for holding a substrate in the vacuum chamber, and an ion quencher disposed between the plasma generator and the base plate holder. When the plasma generator is projected directly onto the base plate holder, the projection image of plasma generator shielded by the ion quencher has an area smaller than the residual image of plasma generator projected onto the base plate holder.