Abstract: A plasma sputtering device including one or a plurality of plasma generating devices each including an insulating tube having an expanding inner diameter and having a gas injection port formed in an end portion or a side portion thereof, a first electromagnet or a permanent magnet group which can apply a static magnetic field, and a high frequency antenna; a second electromagnet which is disposed in a region downstream of the plasma generating device(s) and which can form a curved magnetic force line structure; a target mechanism which includes a permanent magnet embedded therein and a cooling mechanism and which can apply a DC or high frequency voltage; a substrate stage facing the target mechanism; a second permanent magnet group around the substrate stage; and a heat insulating mechanism between a target material and the target mechanism.

Abstract: A plasma sputtering device including one or a plurality of plasma generating devices each including an insulating tube having an expanding inner diameter and having a gas injection port formed in an end portion or a side portion thereof, a first electromagnet or a permanent magnet group which can apply a static magnetic field, and a high frequency antenna; a second electromagnet which is disposed in a region downstream of the plasma generating device(s) and which can form a curved magnetic force line structure; a target mechanism which includes a permanent magnet embedded therein and a cooling mechanism and which can apply a DC or high frequency voltage; a substrate stage facing the target mechanism; a second permanent magnet group around the substrate stage; and a heat insulating mechanism between a target material and the target mechanism.

Abstract: A sputtering apparatus (1) includes: a chamber (10) having an inside maintained in a depressurized state to generate plasma discharge (20); a cathode (22) placed in the chamber (10) and holding a target (21); and a substrate holder (60) holding a substrate (110) so that one surface of the substrate (110) faces the surface of the target (21). The substrate (110) is arranged at an upper portion in the sputtering apparatus (1) with the surface of the substrate (110) facing downward. The target (21) is arranged at a lower portion in the sputtering apparatus (1) with the surface of the target (21) facing upward. The sputtering apparatus (1) includes a heater (65) for heating the substrate (110). The temperature of the substrate (110) is raised by absorbing electromagnetic waves radiated from the heater (65). A method of manufacturing a semiconductor light-emitting element using the sputtering apparatus is also disclosed.

Abstract: The present invention provides a method of manufacturing a solar cell, comprising forming a buffer layer comprising a group-III nitride semiconductor on a substrate using a sputtering method, and forming a group-III nitride semiconductor layer and electrodes on the buffer layer. The group-III nitride semiconductor layer is formed on the buffer layer by at least one selected from the group consisting of the sputtering method, a MOCVD method, an MBE method, a CBE method, and an MLE method, and the electrodes are formed on the group-III nitride semiconductor layer.

Abstract: According to one embodiment, a telephone system includes a plurality of telephone terminals, a first server apparatus and a second server apparatus. The first server apparatus includes a license authentication module and a transmission controller. The license authentication module performs license authentication by comparing a terminal ID included in a registration request with a terminal ID stored in the license memory. The transmission controller reads from the license memory a license authentication code corresponding to a telephone terminal, and transmits to the telephone terminal a license authentication code added check information.

Abstract: A backing plate for use in a sputtering deposition apparatus being capable of stably holding Ga, and a sputtering deposition apparatus which is equipped with the backing plate are provided. Such a backing plate for use in a sputtering deposition apparatus is a backing plate for holding a target material which contains Ga, and at least a contact surface of which coming into contact with the target material is constituted from an easily wettable material having a contact angle to Ga in a liquid state of not more than 90°.

Abstract: According to the present invention, an AlN crystal film seed layer having high crystallinity is combined with selective/lateral growth, whereby a Group III nitride semiconductor multilayer structure more enhanced in crystallinity can be obtained. The Group III nitride semiconductor multilayer structure of the present invention is a Group III nitride semiconductor multilayer structure where an AlN crystal film having a crystal grain boundary interval of 200 nm or more is formed as a seed layer on a C-plane sapphire substrate surface by a sputtering method and an underlying layer, an n-type semiconductor layer, a light-emitting layer and a p-type semiconductor layer, each composed of a Group III nitride semiconductor, are further stacked, wherein regions in which the seed layer is present and is absent are formed on the C-plane sapphire substrate surface and/or regions capable of epitaxial growth and incapable of epitaxial growth are formed in the underlying layer.

Abstract: The present invention provides a deposition method of a multilayered structure composed of a III group nitride compound semiconductor having good crystallinity on a substrate. The multilayered structure comprises at least a buffer layer and an underlying layer from the substrate side, and the buffer layer and the underlying layer are formed by a sputtering method. A deposition temperature of the buffer layer is adjusted to a temperature lower than a deposition temperature of the underlying layer, or the thickness of the buffer layer is adjusted to 5 nm to 500 nm. Furthermore, the multilayered structure comprises at least an underlying layer and a light-emissive layer from the substrate side and the underlying layer is formed by a sputtering method, and the method comprises the step of forming the light-emissive layer by a metal-organic chemical vapor deposition (MOCVD method).

Abstract: A method for the production of a magnetic recording medium (30) includes the steps of depositing a magnetic layer or Co-containing magnetic layer (3) on at least one side of a nonmagnetic substrate (1) and partially implanting atoms into the magnetic layer or Co-containing magnetic layer to partially unmagnetize the magnetic layer or Co-containing magnetic layer, thereby forming nonmagnetic parts (4) and a magnetic recording pattern magnetically separated by the nonmagnetic parts and, in the case of the Co-containing magnetic layer, lowering Co (002) or Co (110) peak strength of a relevant part of the Co-containing magnetic layer as determined by the X-ray diffraction to ½ or less.

Abstract: According to one embodiment, a telephone system includes a plurality of telephone terminals, a first server apparatus and a second server apparatus. The first server apparatus includes a license authentication module and a transmission controller. The license authentication module performs license authentication by comparing a terminal ID included in a registration request with a terminal ID stored in the license memory. The transmission controller reads from the license memory a license authentication code corresponding to a telephone terminal, and transmits to the telephone terminal a license authentication code added check information.

Abstract: Provided is a group-III nitride semiconductor light-emitting device which has a high level of crystallinity and superior internal quantum efficiency and which is capable of enabling acquisition of high level light emission output, and a manufacturing method thereof, and a lamp. An AlN seed layer composed of a group-III nitride based compound is laminated on a substrate 11, and on this AlN seed layer, there are sequentially laminated each layer of an n-type semiconductor layer, a light-emitting layer, and a p-type semiconductor layer respectively composed of a group-III nitride semiconductor, wherein the full width at half-maximum of the X-ray rocking curve of the (0002) plane of the p-type semiconductor layer 16 is 60 arcsec or less, and the full width at half-maximum of the X-ray rocking curve of the (10-10) plane is 250 arcsec or less.

Abstract: According to the present invention, an AlN crystal film seed layer having high crystallinity is combined with selective/lateral growth, whereby a Group III nitride semiconductor multilayer structure more enhanced in crystallinity can be obtained. The Group III nitride semiconductor multilayer structure of the present invention is a Group III nitride semiconductor multilayer structure where an AlN crystal film having a crystal grain boundary interval of 200 nm or more is formed as a seed layer on a C-plane sapphire substrate surface by a sputtering method and an underlying layer, an n-type semiconductor layer, a light-emitting layer and a p-type semiconductor layer, each composed of a Group III nitride semiconductor, are further stacked, wherein regions in which the seed layer is present and is absent are formed on the C-plane sapphire substrate surface and/or regions capable of epitaxial growth and incapable of epitaxial growth are formed in the underlying layer.

Abstract: The present invention aims to provide a method of producing a magnetic recording medium which is a method of producing a magnetic recording medium having a magnetically-separated magnetic recording pattern, the method including: forming a magnetic layer on a non-magnetic substrate; then exposing a surface of the magnetic layer partially to reactive plasma, or a reactive ion generated in the plasma to amorphize the portion of the magnetic layer.

Abstract: The present invention provides a group-III nitride compound semiconductor light-emitting device having high productivity and good emission characteristics, a method of manufacturing a group-III nitride compound semiconductor light-emitting device, and a lamp. A method of manufacturing a group-III nitride compound semiconductor light-emitting device includes a step of forming on a substrate 11 a semiconductor layer made of a group-III nitride compound semiconductor including Ga as a group-III element using a sputtering method. The substrate 11 and a sputtering target are arranged so as to face each other, and a gap between the substrate 11 and the sputtering target is in the range of 20 to 100 mm. In addition, when the semiconductor layer is formed by the sputtering method, a bias of more than 0.1 W/cm2 is applied to the substrate 11. Further, when the semiconductor layer is formed, nitrogen and argon are supplied into a chamber used for sputtering.

Abstract: A discrete track-type magnetic recording medium (30) includes a nonmagnetic substrate (1), a magnetic recording track and a servo signal pattern which are provided on at least one side of the nonmagnetic substrate, and a nonmagnetic part (4) consisting of a nonmagnetic alloy containing Si for physically separating the magnetic recording track and the servo signal pattern. A magnetic recording and reproducing device comprising, in combination, the magnetic recording medium (30), a driving part (26) serving to drive the magnetic recording medium in a direction of recording, a magnetic head (27) composed of a recording part and a reproducing part, a device (28) to impart motion to the magnetic head relative to the magnetic recording medium, and a recording and reproducing signal processing device (29) for entering a signal into the magnetic head and reproducing an output signal from the magnetic head.

Abstract: According to the present invention, an AlN crystal film seed layer having high crystallinity is combined with selective/lateral growth, whereby a Group III nitride semiconductor multilayer structure more enhanced in crystallinity can be obtained. The Group III nitride semiconductor multilayer structure of the present invention is a Group III nitride semiconductor multilayer structure where an AlN crystal film having a crystal grain boundary interval of 200 nm or more is formed as a seed layer on a C-plane sapphire substrate surface by a sputtering method and an underlying layer, an n-type semiconductor layer, a light-emitting layer and a p-type semiconductor layer, each composed of a Group III nitride semiconductor, are further stacked, wherein regions in which the seed layer is present and is absent are formed on the C-plane sapphire substrate surface and/or regions capable of epitaxial growth and incapable of epitaxial growth are formed in the underlying layer.

Abstract: A method for producing a group III nitride semiconductor light-emitting device including: an intermediate layer formation step in which an intermediate layer containing group III nitride is formed on a substrate by sputtering, and a laminate semiconductor formation step in which an n-type semiconductor layer having a base layer, a light-emitting layer, and a p-type semiconductor layer are laminated on the intermediate layer in this order, wherein the method includes a pretreatment step in which the intermediate layer is treated using plasma between the intermediate layer formation step and the laminate semiconductor formation step, and a formation step for the base layer which is included in the laminate semiconductor formation step is a step for laminating the base layer by sputtering.

Abstract: A method for manufacturing a Group III nitride semiconductor light-emitting device according to the present invention, comprising forming, on a substrate, a semiconductor layer comprised of a Group III nitride compound semiconductor containing Ga as a Group III element by a sputtering method, wherein during the formation of the semiconductor layer, sputtering is performed under the condition where at least the surface layer of a sputtering target comprised of Ga is liquefied.

Abstract: An object of the present invention is to obtain a group III nitride compound semiconductor stacked structure where a group III nitride compound semiconductor layer having good crystallinity is stably stacked on a dissimilar substrate. The group III nitride compound semiconductor stacked structure of the present invention is a group III nitride compound semiconductor stacked structure comprising a substrate having provided thereon a first layer comprising a group III nitride compound semiconductor and a second layer being in contact with the first layer and comprising a group III nitride compound semiconductor, wherein the first layer contains a columnar crystal with a definite crystal interface and the columnar crystal density is from 1×103 to 1×105 crystals/?m2.

Abstract: According to one embodiment, a conference system which is provided with a plurality of communication terminals, a communication network connecting the plurality of communication terminals thereto and forming a communication environment, and a server apparatus actualizing a conference among users by using the communication network, wherein each of the communication terminals includes a notice processor notifying an acquisition request including the fact of a request to acquire multimedia data and identification information to the server apparatus, and a storage unit storing the multimedia data, and the server apparatus includes a memory unit associating a communication terminal that is a request origin with the identification information, and storing them, an inquiry processor inquiring a possibility to become the route of the multimedia data, and a transmission processor transmitting the multimedia data to the communication terminal of the request origin via the communication terminal of the route.