Abstract: A processor implemented method including outputting guide information to guide a capture of an image of a predetermined area via a camera of a mobile terminal including the processor, inputting a first exterior image of a vehicle, the first exterior image being captured based on the output guide information and a second exterior image of the vehicle stored in advance to a processor including a deep learning model, matching the first exterior image and the second exterior image with each other to acquire a matched image, masking a detected area from the predetermined image within the matched image as a masked area, and determining whether an exterior of the vehicle has been damaged and a type of damage based on the masked area.

Abstract: A system and method for providing a traffic accident handling service for a traffic accident are disclosed, where the method includes acquiring state information of a personal mobility device via a sensor and a camera of the personal mobility device, analyzing the traffic accident based on the acquired state information, receiving accident handling information corresponding to the traffic accident, and providing accident handling guide information based on the accident handling information.

Abstract: An electrochemical biosensor using a sensing system includes a working electrode including an active surface modified through a linker; and an auxiliary electrode. The sensor has a high current value compared with an existing sensor and retains excellent stability and sensitivity, and thus can be expected to be easily used for sensing various kinds of biomaterials.

Abstract: A metal nanowire according to an embodiment of the invention includes at least one bent portion. An angle (?) between an n-th wire portion and an (n+1)-th wire portion connected to the n-th wire portion through an n-th bent portion satisfies an inequation of 0°<?<180°.

Abstract: A metal nanowire according to an embodiment of the invention includes at least one bent portion. An angle (?) between an n-th wire portion and an (n+1)-th wire portion connected to the n-th wire portion through an n-th bent portion satisfies an inequation of 0°<?<180°.

Abstract: A metal nanowire according to an embodiment of the invention includes at least one bent portion. An angle (?) between an n-th wire portion and an (n+1)-th wire portion connected to the n-th wire portion through an n-th bent portion satisfies an inequation of 0°<?<180°. Also, a metal nanowire according to another embodiment of the invention includes at least two wire portions. The metal nanowire includes an n-th wire portion and an (n+1)-th wire portion connected to the n-th wire portion. A diameter of the n-th wire portion is different from a diameter of the (n+1)-th wire portion. In addition, a core-shell nanowire according to yet another embodiment includes a nanowire core; and a metal-compound shell formed on the nanowire core. A method of manufacturing a metal nanowire according to an embodiment includes preparing a reaction mixture and synthesizing a nanowire.

Abstract: An electrochemical biosensor using a sensing system includes a working electrode including an active surface modified through a linker; and an auxiliary electrode. The sensor has a high current value compared with an existing sensor and retains excellent stability and sensitivity, and thus can be expected to be easily used for sensing various kinds of biomaterials.

Abstract: Provided is a method for manufacturing a gas sensor according to an exemplary embodiment of the present invention including: a) forming a pair of photoresist electrodes spaced apart from each other and a photoresist wire connecting upper portions of the pair of photoresist electrodes to each other by exposing and developing a first photoresist coated on a substrate; b) forming a pair of carbon electrodes and a carbon wire that are connected to be integrated with each other, by pyrolyzing the pair of photoresist electrodes and the photoresist wire; and c) forming metal oxide nanowires on a surface of the carbon wire.

Abstract: A metal nanowire according to an embodiment of the invention includes at least one bent portion. An angle (?) between an n-th wire portion and an (n+1)-th wire portion connected to the n-th wire portion through an n-th bent portion satisfies an inequation of 0°<?<180°.

Abstract: A metal nanowire according to an embodiment of the invention includes at least one bent portion. An angle (?) between an n-th wire portion and an (n+1)-th wire portion connected to the n-th wire portion through an n-th bent portion satisfies an inequation of 0°<?<180°.

Abstract: A nanowire according to an embodiment of the invention comprises a nanowire core and a metal-compound coated on the nanowire core, wherein the nanowire core comprises at least two bent portions, and wherein an angle (?) between an n-th wire portion and an (n+1)-th wire portion connected to the n-th wire portion through an n-th bent portion satisfies an inequation of 0<?<180°.

Abstract: An electrochemical biosensor using a sensing system includes a working electrode including an active surface modified through a linker; and an auxiliary electrode. The sensor has a high current value compared with an existing sensor and retains excellent stability and sensitivity, and thus can be expected to be easily used for sensing various kinds of biomaterials.

Abstract: Disclosed is a method for manufacturing a biosensor comprising (a) forming an insulating layer in an electrode region; (b) coating the first photoresist layer on the insulating layer; (c) performing the first exposing process on the first electrode region through the first photomask; (d) removing unexposed area of the first photoresist layer except for the first electrode region using development; (e) coating the second photoresist layer on the first electrode region and the insulating layer after the step (d); (f) performing the second exposing process on the second electrode regions through the second photomask; (g) performing the third exposing process on the top portion of the second photoresist layer through a photomask with open areas in the shape of micro-sized wires connecting the second electrode regions; (h) removing the second photoresist layer except for the portions exposed in the steps (c), (f) and (g) using development.

Abstract: The present invention provides a method for manufacturing a suspended single carbon nanowire and piled nano-electrode pairs, and a suspended single carbon nanowire and piled nano-electrode pairs manufactured using said method. A suspended single carbon nanowire, which is manufactured at a high yield by the method for manufacturing a suspended single carbon nanowire according to the present invention, has a minimized dimension, and a suspended carbon nanomesh, which is manufactured at a high yield by the method for manufacturing piled nano-electrode pairs according to the present invention, is thin and dense. The present invention also provides a gas sensor or an electrochemical sensor, to which a suspended single carbon nanowire and piled nano-electrode pairs manufactured by the method according to the present invention are applied.

Abstract: Provided is a method for manufacturing a gas sensor according to an exemplary embodiment of the present invention including: a) forming a pair of photoresist electrodes spaced apart from each other and a photoresist wire connecting upper portions of the pair of photoresist electrodes to each other by exposing and developing a first photoresist coated on a substrate; b) forming a pair of carbon electrodes and a carbon wire that are connected to be integrated with each other, by pyrolyzing the pair of photoresist electrodes and the photoresist wire; and c) forming metal oxide nanowires on a surface of the carbon wire.

Abstract: The present invention provides a method for manufacturing a suspended single carbon nanowire and piled nano-electrode pairs, and a suspended single carbon nanowire and piled nano-electrode pairs manufactured using said method. A suspended single carbon nanowire, which is manufactured at a high yield by the method for manufacturing a suspended single carbon nanowire according to the present invention, has a minimized dimension, and a suspended carbon nanomesh, which is manufactured at a high yield by the method for manufacturing piled nano-electrode pairs according to the present invention, is thin and dense. The present invention also provides a gas sensor or an electrochemical sensor, to which a suspended single carbon nanowire and piled nano-electrode pairs manufactured by the method according to the present invention are applied.

Abstract: Disclosed is a method for manufacturing a biosensor comprising (a) forming an insulating layer in an electrode region; (b) coating the first photoresist layer on the insulating layer; (c) performing the firs exposing process on the first electrode region through the first photomask; (d) removing unexposed area of the first photoresist layer except for the first electrode region using development; (e) coating the second photoresist layer on the first electrode region and the insulating layer after the step (d); (f) performing the second exposing process on the second electrode regions through the second photomask; (g) performing the third exposing process on the top portion of the second photoresist layer through a photomask with open areas in the shape of micro-sized wires connecting the second electrode regions; (h) removing the second photoresist layer except for the portions exposed in the steps (c), (f) and (g) using development.