| KANAGAWA ACADEMY OF SCIENCE AND TECHNOLOGY Patent applications |
| Patent application number | Title | Published |
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| 20120088295 | DEVICE FOR CONCENTRATING AND SEPARATING CELLS - Provided is a device for concentrating and separating cells, which has a function for continuously concentrating cells; a function for then continuously arranging the concentrated cells in predetermined regions of a flow path; a function for simultaneously identifying shape and fluorescent emission in one-cell units on the basis of cell concentration and purification images, which serve to continuously separate and purify cells that have different properties in that they are either attracted to or repelled by an induction electrophoresis force of a predetermined frequency; and a function for identifying cells on the basis of this shape and fluorescent emission information and thereby separating and purifying the cells. | 04-12-2012 |
| 20100247429 | MICROCHIP, MICROCHIP DEVICE AND EVAPORATION METHOD USING MICROCHIP - Provided is a microchip capable of integrating liquid evaporation as an operation on the microchip. In the microchip | 09-30-2010 |
| 20100196665 | Anti-Reflective Film and Production Method Thereof, and Stamper for Producing Anti-Reflective Film and Production Method Thereof - In this method for producing an anti-reflective film, pores are formed on a surface of a polymer molding material to continuously change a refractive index and then reduce reflectance, in which anodic oxidized porous alumina, in which pores having a tapered shape and whose pore diameter continuously changes, are formed by repeating anodic oxidation at about the same formation voltage and pore diameter enlargement treatment, is used as a mold, or a stamper, which is produced by using the anodic oxidized porous aluminum as a mold, is used as a mold. | 08-05-2010 |
| 20100178466 | Anti-Reflective Film and Production Method Thereof, and Stamper for Producing Anti-Reflective Film and Production Method Thereof - In this method for producing an anti-reflective film, pores are formed on a surface of a polymer molding material to continuously change a refractive index and then reduce reflectance, in which anodic oxidized porous alumina, in which pores having a tapered shape and whose pore diameter continuously changes, are formed by repeating anodic oxidation at about the same formation voltage and pore diameter enlargement treatment, is used as a mold, or a stamper, which is produced by using the anodic oxidized porous aluminum as a mold, is used as a mold. | 07-15-2010 |
| 20100177392 | Anti-Reflective Film and Production Method Thereof, and Stamper for Producing Anti-Reflective Film and Production Method Thereof - In this method for producing an anti-reflective film, pores are formed on a surface of a polymer molding material to continuously change a refractive index and then reduce reflectance, in which anodic oxidized porous alumina, in which pores having a tapered shape and whose pore diameter continuously changes, are formed by repeating anodic oxidation at about the same formation voltage and pore diameter enlargement treatment, is used as a mold, or a stamper, which is produced by using the anodic oxidized porous aluminum as a mold, is used as a mold. | 07-15-2010 |
| 20100163931 | GROUP III-V NITRIDE LAYER AND METHOD FOR PRODUCING THE SAME - There is disclosed a hexagonal Group III-V nitride layer exhibiting high quality crystallinity capable of improving the properties of a semiconductor device such as a light emitting element. This nitride layer is a Group III-V nitride layer belonging to hexagonal crystal formed by growth on a substrate having a different lattice constant, which has a growth-plane orientation of {1-100} and in which a full width at half maximum b | 07-01-2010 |
| 20100062558 | Method for producing transparent conductive layer comprising TIO2 and method for producing semiconductor light-emitting element utilizing said method for producing transparent conductive layer - When a p-layer | 03-11-2010 |
| 20100060981 | Circular Dichroic Thermal Lens Microscope - An objective of the present invention is to provide a circular dichroism thermal lens microscope apparatus capable of identifying and quantifying optically active samples in ultra-trace amounts, and which has a higher sensitivity than conventional apparatuses. | 03-11-2010 |
| 20100006134 | NANOTUBE-SHAPED TITANIA AND PROCESS FOR PRODUCING THE SAME - A nanotube-shaped titania having an aspect ratio of 6 or greater can be produced by anodizing a titanium metal or an alloy containing mainly titanium in an electrolyte solution containing a halogen atom-containing ion, such as a perchloric acid aqueous solution. | 01-14-2010 |
| 20090147405 | METHOD FOR MANUFACTURING MAGNETIC RECORDING MEDIUM, MAGNETIC RECORDING MEDIUM MANUFACTURED BY THE SAME, AND MAGNETIC RECORDING APPARATUS INCORPORATING THE MAGNETIC RECORDING MEDIUM - A method for manufacturing a magnetic recording medium which has a substrate and a magnetic layer formed on the substrate, the method including: forming the magnetic layer over a convexo-concave pattern provided on a surface of a mold, and releasing the mold from the magnetic layer formed on the substrate. | 06-11-2009 |
| 20090035793 | Microchip for cell response evaluation - In a microchip which enables cell cultivation and accurate cell count measurement, fine particles affixed with cells are trapped within a passage by making the minimum width of a solution and fine particle inlet into a cell culture portion larger than the maximum diameter of the fine particles, and making the width of an outlet smaller than the maximum diameter of the fine particles. | 02-05-2009 |
| 20080308833 | Group III nitride-based compound semiconductor light-emitting device - The refractive index of a titanium oxide layer is modified by adding an impurity (e.g., niobium (Nb)) thereto within a range where good electrical conductivity is obtained. The Group III nitride-based compound semiconductor light-emitting device of the invention includes a sapphire substrate, an aluminum nitride (AlN) buffer layer, an n-contact layer, an n-cladding layer, a multiple quantum well layer (emission wavelength: 470 nm), a p-cladding layer, and a p-contact layer. On the p-contact layer is provided a transparent electrode made of niobium titanium oxide and having an embossment. An electrode is provided on the n-contact layer. An electrode pad is provided on a portion of the transparent electrode. Since the transparent electrode is formed from titanium oxide containing 3% niobium, the refractive index with respect to light (wavelength: 470 nm) becomes almost equal to that of the p-contact layer. Thus, the total reflection at the interface between the p-contact layer and the transparent electrode can be avoided to the smallest possible extent. In addition, by virtue of the embossment, light extraction performance is increased by 30%. | 12-18-2008 |
| 20080241073 | Polymeric Micelle Type Mri Imaging Agent - A contrast agent for magnetic resonance imaging which stably circulates in the blood for a long period and which targets solid tumors, with which clear images of cancers may be obtained is disclosed. The contrast agent for magnetic resonance imaging comprises as an effective ingredient a polymeric micelle having gadolinium (Gd) atoms in an inner core and an outer shell including hydrophilic polymer chain segments, which micelle is delivered to a tissue(s) and/or site(s) of solid tumor(s) in vivo, whose micellar structure is dissociated after being accumulated in the tissue(s) and/or site(s). | 10-02-2008 |
| 20080220290 | Magnetic recording medium and manufacturing method for the same - To provide a magnetic recording medium manufacturing method capable of transferring a pattern that can serve as a source for forming anodized alumina-nanoholes with high precision and realizing high productivity, and a large-capacity magnetic recording medium capable of achieving high density recording. The method includes forming a metallic layer on a concavo-convex pattern formed on a surface of a mold; bonding a substrate using an adhesive to a surface of the metallic layer on the side opposite to the mold; separating the mold from the metallic layer; forming, through nanohole formation treatment, a porous layer in which a plurality of nanoholes are formed to orient in a direction substantially perpendicular to a substrate plane by using as a nanohole source a concavo-convex pattern which has been formed by transferring the concavo-convex pattern in the mold to the metallic layer; and charging a magnetic material inside the nanoholes. | 09-11-2008 |
