Abstract: According to one embodiment, a method including supplying a liquid onto a substrate, solidifying the liquid on the substrate to form a solidified body, and melting the solidified body of the liquid on the substrate is provided. When solidifying the liquid, an internal pressure of the liquid on the substrate is varied.

Abstract: According to one embodiment, a method including supplying a liquid onto a substrate, solidifying the liquid on the substrate to form a solidified body, and melting the solidified body of the liquid on the substrate is provided. When solidifying the liquid, an internal pressure of the liquid on the substrate is varied.

Abstract: A driving evaluation device includes a first memory and a first processor that is coupled to the first memory. The first processor is configured to cause driving information pertaining to dangerous driving incidents collected from a vehicle to be stored in a storage unit together with types and danger ratings of the dangerous driving incidents, generate evaluation information pertaining to a driver of the vehicle based on the driving information collected from the vehicle, retrieve dangerous driving incidents pertaining to the driver based on at least one of the types or the danger ratings, and provide to a user the evaluation information that has been generated and driving information pertaining to the dangerous driving incidents that have been retrieved.

Abstract: A driving evaluation device includes a first memory and a first processor that is coupled to the first memory. The first processor is configured to cause driving information pertaining to dangerous driving incidents collected from a vehicle to be stored in a storage unit together with types and danger ratings of the dangerous driving incidents, generate evaluation information pertaining to a driver of the vehicle based on the driving information collected from the vehicle, retrieve dangerous driving incidents pertaining to the driver based on at least one of the types or the danger ratings, and provide to a user the evaluation information that has been generated and driving information pertaining to the dangerous driving incidents that have been retrieved.

Abstract: A driving evaluation device that acquires dangerous driving detection results for a plurality of vehicles and characteristic information indicating supplementary characteristics for at least one of a driver characteristic or an environmental characteristic; and groups the acquired dangerous driving detection results according to the characteristic information, and derives a relative driving evaluation result for each driver of the plurality of vehicles, based on the grouped detection results.

Abstract: A dangerous driving detection device includes: an acquisition section that acquires image information, which expresses captured images that are captured by an imaging section provided at a vehicle, and vehicle information that expresses a state of the vehicle; plural detection sections that, based on the image information and the vehicle information acquired by the acquisition section, detect types of dangerous driving that are respectively different from one another; and a deriving section that, based on results of detection of the plural detection sections, derives a degree of danger of dangerous driving of a driver.

Abstract: A moving body obstruction detection device includes: a detection section that detects a predetermined moving body within an image that is captured by an imaging section provided at a vehicle; and an inferring section that infers a moving body state that relates to the moving body crossing a road, based on a position of a bounding box that surrounds the moving body detected by the detection section.

Abstract: A determination device includes a processor. The processor is configured to detect an object in an image captured by an image capture section provided at a vehicle, generate a determination area in accordance with a direction of movement of the vehicle based on travel information of the vehicle and based on a position and a speed of the object, and determine danger to be present in a case in which the object is present in the determination area.

Abstract: According to one embodiment, a method including supplying a liquid onto a substrate, solidifying the liquid on the substrate to form a solidified body, and melting the solidified body of the liquid on the substrate is provided. When solidifying the liquid, an internal pressure of the liquid on the substrate is varied.

Abstract: A substrate cleaning method includes: steps (a) to (d). In step (a), a liquid is supplied onto a nanoimprint template substrate that has a patterned surface with foreign particles to form a liquid film on the patterned surface. In step (b), the liquid film is solidified to form a solidified film including the foreign particles. In step (c), the substrate is reversed. In step (d), the solidified film is melted to remove the foreign particles.

Abstract: According to one embodiment, a method including supplying a liquid onto a substrate, solidifying the liquid on the substrate to form a solidified body, and melting the solidified body of the liquid on the substrate is provided. When solidifying the liquid, an internal pressure of the liquid on the substrate is varied.

Abstract: A substrate cleaning method includes: steps (a) to (d). In step (a), a liquid is supplied onto a nanoimprint template substrate that has a patterned surface with foreign particles to form a liquid film on the patterned surface. In step (b), the liquid film is solidified to form a solidified film including the foreign particles. In step (c), the substrate is reversed. In step (d), the solidified film is melted to remove the foreign particles.

Abstract: According to one embodiment, an apparatus for manufacturing a template includes a vacuum chamber, an electrode and an adjustor. The vacuum chamber includes an inlet and an exhaust port of a reactive gas. The vacuum chamber is capable of maintaining an atmosphere depressurized below atmospheric pressure. The electrode is provided in an interior of the vacuum chamber. A high frequency voltage is applied to the electrode. A substrate is placed on the electrode. The substrate has a back surface on a side of the electrode. A recess is provided in the back surface. The adjustor is inserted into the recess. The adjustor is insulative.

Abstract: An oxide superconductor wire includes: a tape-shaped oxide superconductor laminate that is formed by providing an intermediate layer on a front surface side of a metal tape-shaped substrate, providing an oxide superconductor layer on the intermediate layer, and providing a protective layer on the oxide superconductor layer; and a coating member that includes a metal tape and a low melting point metal layer, in which the metal tape has a wider width than that of the oxide superconductor laminate and covers the protective layer surface of the oxide superconductor laminate, both side surfaces of the oxide superconductor laminate, and both end portions of a substrate back surface side in a width direction thereof, and both end portions of the metal tape in a width direction thereof are provided to cover both the end portions of the substrate back surface.

Abstract: According to one embodiment, an apparatus for manufacturing a template includes a vacuum chamber, an electrode and an adjustor. The vacuum chamber includes an inlet and an exhaust port of a reactive gas. The vacuum chamber is capable of maintaining an atmosphere depressurized below atmospheric pressure. The electrode is provided in an interior of the vacuum chamber. A high frequency voltage is applied to the electrode. A substrate is placed on the electrode. The substrate has a back surface on a side of the electrode. A recess is provided in the back surface. The adjustor is inserted into the recess. The adjustor is insulative.

Abstract: An oxide superconductor wire including: a superconductor laminate including a tape-shaped substrate, an interlayer, an oxide superconductor layer, and a protection layer which are formed on the substrate; a metal stabilization layer covering the periphery of the superconductor laminate; a first electrically conductive joint material arranged between the superconductor laminate and the metal stabilization layer; and a sealing member formed from a metal foil, connected to a terminal of the superconductor laminate, and extending in the longitudinal direction of the superconductor laminate, wherein the metal stabilization layer includes an extension part formed so as to cover the periphery of the sealing member, and wherein the first electrically conductive joint material includes an extension part arranged between the extension part of the metal stabilization layer and the sealing member and formed so as to cover the periphery of the sealing member.

Abstract: An oxide superconductor wire including: a superconductor laminate including a tape-shaped substrate, an interlayer, an oxide superconductor layer, and a protection layer which are formed on the substrate; a metal stabilization layer covering the periphery of the superconductor laminate; a first electrically conductive joint material arranged between the superconductor laminate and the metal stabilization layer; and a sealing member formed from a metal foil, connected to a terminal of the superconductor laminate, and extending in the longitudinal direction of the superconductor laminate, wherein the metal stabilization layer includes an extension part formed so as to cover the periphery of the sealing member, and wherein the first electrically conductive joint material includes an extension part arranged between the extension part of the metal stabilization layer and the sealing member and formed so as to cover the periphery of the sealing member.

Abstract: An oxide superconductor wire including: an oxide superconductor laminate comprising: a tape-shaped substrate, an interlayer laminated on the substrate, an oxide superconductor layer laminated on the interlayer, and a protection layer which is formed of Ag or an Ag alloy and laminated on the oxide superconductor layer; and a stabilization layer which is formed of a metal tape and formed on the protection layer of the superconductor laminate via a low melting point metal layer, wherein the thickness of the protection layer is 5 ?M or less, and wherein a volume resistivity of the stabilization layer at room temperature is no less than 3.8 ??·cm and no more than 15 ??·cm.

Abstract: An oxide superconductor wire includes: a tape-shaped oxide superconductor laminate that is formed by providing an intermediate layer on a front surface side of a metal tape-shaped substrate, providing an oxide superconductor layer on the intermediate layer, and providing a protective layer on the oxide superconductor layer; and a coating member that includes a metal tape and a low melting point metal layer, in which the metal tape has a wider width than that of the oxide superconductor laminate and covers the protective layer surface of the oxide superconductor laminate, both side surfaces of the oxide superconductor laminate, and both end portions of a substrate back surface side in a width direction thereof, and both end portions of the metal tape in a width direction thereof are provided to cover both the end portions of the substrate back surface.

Abstract: According to one embodiment, an apparatus for manufacturing a template includes a vacuum chamber, an electrode and an adjustor. The vacuum chamber includes an inlet and an exhaust port of a reactive gas. The vacuum chamber is capable of maintaining an atmosphere depressurized below atmospheric pressure. The electrode is provided in an interior of the vacuum chamber. A high frequency voltage is applied to the electrode. A substrate is placed on the electrode. The substrate has a back surface on a side of the electrode. A recess is provided in the back surface. The adjustor is inserted into the recess. The adjustor is insulative.