Abstract: An electronic device includes a sensor, a memory, and a display, and a processor. The processor is configured to determine bio-information and blood pressure information of a user measured through the sensor, determine reliability of calibration of the blood pressure information, based on at least one of elapsed time of the calibration, the bio-information, and the blood pressure information, determine, based on the reliability of the calibration, whether an event associated with the calibration occurs, and display a user interface (UI) to request another calibration, through the display, when the event is determined to have occurred.

Abstract: An electronic device can comprise: a sensor module; and a processor for acquiring periphery state information indicating information on the outside of the electronic device and/or device state information indicating information on the inside of the electronic device, acquiring a measurement profile including information regarding target gas to be measured and a detection period of the target gas on the basis of the periphery state information and/or the device state information, and detecting the target gas through the sensor module according to the measurement profile.

Abstract: An apparatus and method for measuring a temperature in an electronic device. An amount of light of an optical signal reflected off of an object is measured, and a size of a temperature measurement expectation area on the object based is determined based on the measured amount of light. A temperature measurement guide message is output based on a result of comparing the determined size and a reference area.

Abstract: An electronic device includes a sensor, a memory, and a display, and a processor. The processor is configured to determine bio-information and blood pressure information of a user measured through the sensor, determine reliability of calibration of the blood pressure information, based on at least one of elapsed time of the calibration, the bio-information, and the blood pressure information, determine, based on the reliability of the calibration, whether an event associated with the calibration occurs, and display a user interface (UI) to request another calibration, through the display, when the event is determined to have occurred.

Abstract: An electronic apparatus and an ultraviolet avoidance information providing method are provided. The electronic apparatus includes a display; a biometric information acquisition module that acquires biometric information of a user; a location information acquisition module that acquires location information of a particular location; an ultraviolet intensity information acquisition module that acquires ultraviolet intensity information corresponding to the acquired location information; and a processor that controls the display to display ultraviolet avoidance information for avoiding ultraviolet light at the particular location based on the acquired biometric information and the acquired ultraviolet intensity information.

Abstract: An electronic device according to various exemplary embodiments of the present disclosure includes: a motion sensor; a temperature sensor configured to acquire temperature information on an external object; an image sensor configured to acquire an image on the external object; and a processor, and the processor is configured to: identify a motion of the electronic device and a motion of the external object using the motion sensor or the image; when the motion falls within a specified range, acquire the temperature information in a first method; when the motion falls within another specified range, acquire the temperature information in a second method; and provide an indicator corresponding to the temperature information through a display functionally connected with the electronic device.

Abstract: Provided are a nanopore device with resolution improved by graphene nanopores, and a method of manufacturing the same. The nanopore device includes: a first insulating layer; a graphene layer disposed on the first insulating layer and having a nanopore formed at a center portion of the graphene layer; and first and second electrode layers disposed respectively at both sides of the nanopore on a top surface of the graphene layer, wherein a center region of the first insulating layer is removed such that the center portion of the graphene layer is exposed to the outside.

Abstract: An electronic apparatus and an ultraviolet avoidance information providing method are provided. The electronic apparatus includes a display; a biometric information acquisition module that acquires biometric information of a user; a location information acquisition module that acquires location information of a particular location; an ultraviolet intensity information acquisition module that acquires ultraviolet intensity information corresponding to the acquired location information; and a processor that controls the display to display ultraviolet avoidance information for avoiding ultraviolet light at the particular location based on the acquired biometric information and the acquired ultraviolet intensity information.

Abstract: An apparatus and method for measuring a temperature in an electronic device. An amount of light of an optical signal reflected off of an object is measured, and a size of a temperature measurement expectation area on the object based is determined based on the measured amount of light. A temperature measurement guide message is output based on a result of comparing the determined size and a reference area.

Abstract: A nanosensor may include a substrate that has a hole formed therein, a first insulating layer that is disposed on the substrate and has a nanopore formed therein, first and second electrodes that are disposed on the first insulating layer and are spaced apart from each other, first and second electrode pads that are disposed on the first and second electrodes, respectively, and a protective layer disposed on the first and second electrode pads. A method of manufacturing a nanosensor may include forming a first insulating layer, graphene, and a metal layer on a substrate, patterning the metal layer and the graphene, forming a protective layer on a portion of the graphene and the metal layer, exposing a portion of the graphene by removing a portion of the protective layer, forming a hole in the substrate, and forming a nanopore in the first insulating layer and the graphene to be connected to the hole.

Abstract: A biomolecule detection apparatus comprising a nanopore device having a front surface and rear surface and including a nanopore having a nano-sized diameter; a reservoir disposed adjacent to a rear surface of the nanopore device; and a power supply unit comprising a first electrode disposed in a front of the nanopore device; a second electrode disposed inside the reservoir; and a third electrode disposed adjacent the nanopore and between the first electrode and the second electrode; as well as a method of using the biomolecule detection apparatus to detect a biomolecule in a sample.

Abstract: Nanosensors including graphene and methods of manufacturing the same. A nanosensor includes a first insulating layer in which a first nanopore is formed; a graphene layer that is disposed on the first insulating layer and having a second nanopore or a nanogap formed therein adjacent to the first nanopore; and a marker element that is disposed adjacent to the graphene layer and identifies a position of the graphene layer.

Abstract: A method of determining or estimating a nucleotide sequence of a nucleic acid by using a device with a nanopore.

Abstract: Provided is a device for determining a monomer molecule sequence of a polymer including different electrodes, and a method of efficiently determining a monomer molecule sequence of a polymer.

Abstract: A nanopore device including a nanopore formed by penetrating a thin layer, a nanochannel formed at an entrance of the nanopore, and a filler in the nanochannel, as well as a method of fabricating the nanopore device and an apparatus including the nanopore device.

Abstract: Provided are a method of manufacturing graphene, carbon nanotubes, fullerene, graphite, or a combination thereof having a regulated resistance, and a material manufactured using the method.

Abstract: A nanogap sensor includes a first layer in which a micropore is formed; a graphene sheet disposed on the first layer and including a nanoelectrode region in which a nanogap is formed, the nanogap aligned with the micropore; a first electrode formed on the grapheme sheet; and a second electrode formed on the graphene sheet, wherein the first electrode and the second electrode are connected to respective ends of the nanoelectrode region.

Abstract: Provided are a nanopore device with resolution improved by graphene nanopores, and a method of manufacturing the same. The nanopore device includes: a first insulating layer; a graphene layer disposed on the first insulating layer and having a nanopore formed at a center portion of the graphene layer; and first and second electrode layers disposed respectively at both sides of the nanopore on a top surface of the graphene layer, wherein a center region of the first insulating layer is removed such that the center portion of the graphene layer is exposed to the outside.

Abstract: The method of manufacturing a graphene device includes forming an insulating material layer on a substrate, forming first and second metal pads on the insulating material layer spaced apart from each other, forming a graphene layer having a portion defined as an active area between the first and second metal pads on the insulating material layer, forming third and fourth metal pads on the graphene layer spaced apart from each other with the active area therebetween, the third and fourth metal pads extending above the first metal pad and the second metal pad, respectively, forming a first protection layer to cover all the first and second metal pads, the graphene layer, and the third and fourth metal pads, and etching an entire surface of the first protection layer until only a residual layer made of a material for forming the first protection layer remains on the active area.

Abstract: Provided are a method of manufacturing graphene, carbon nanotubes, fullerene, graphite, or a combination thereof having a regulated resistance, and a material manufactured using the method.