Abstract: Provided are a gas storage structure and a gas storage apparatus including the gas storage structure. The gas storage structure includes a gas storage part including an opening thereon and an entrance control part disposed on the opening and including a gate.

Abstract: Provided is a biosensor which can detect a specific biomaterial by an interaction between target molecules and probe molecules, and a manufacturing method thereof. The biosensor includes: a first conductive semiconductor substrate; a second conductive doping layer formed on the semiconductor substrate; an electrode formed on top of both opposite ends of the doping layer; and probe molecules immobilized on the doping layer.

Abstract: Provided is a method for selectively functionalizing unmodified solid surface, not oxidized and nitrified, into an aldehyde group, and a method for immobilizing an active material such as bio material or functional material on the functionalized aldehyde solid surface through strong and stable chemical bonding. Differently from a conventional method immobilizing deoxyribonucleic acid (DNA) using a cross linker, the method of the present invention does not require a cross linker reaction step to thereby shorten a process. Also, since a cross linker is absent, the monomolecular layer on the surface of a device is thin, which reduces a perturbation effect by molecular layer. This is useful in fabrication of molecular electronic devices and bio-active devices.

Abstract: Provided is a gas treating apparatus. The gas treating apparatus includes a storage chamber having a top wall, a bottom wall facing the top wall, and a sidewall connecting the top wall to the bottom wall, a gas collecting unit provided in the storage chamber and storing ionized gas, and an electromagnetic field generator converting a moving direction of the ionized gas. The electromagnetic generator includes at least one of a magnetic field generator generating a magnetic field in the storage chamber and an electric field generator generating an electric field in the storage chamber.

Abstract: There are provided a nanowire filter, a method for manufacturing the same, a filtering apparatus having the same, and a method for removing material adsorbed on the nanowire filter. The filtering apparatus includes: a filter having a supporting member and a plurality of nanowires supported on the supporting member and arranged in a crystallized state; and a body into which the filter is inserted and secured, and which has an inlet for guiding an introduced fluid to the filter and an outlet for discharging the fluid filtered through the filter to the outside.

Abstract: Provided is a biosensor with a three-dimensional multi-layered structure, a method for manufacturing the biosensor, and a biosensing apparatus including the biosensor. The biosensing apparatus includes: a chamber having an inlet through which a fluid containing a biomaterial enters and an outlet through which the fluid exits; and a plurality of biosensors inserted and fixed in the chamber. Each biosensor includes: a support unit having a fluid channel through which a fluid containing a biomaterial flows; and a sensing unit disposed on the support unit in such a way that the sensing unit is exposed three-dimensionally in the fluid channel of the support unit, the sensing unit being surface-treated with a reactive material that is to react with the biomaterial flowing through the fluid channel.

Abstract: Provided are a substrate for analyzing the coverage of self-assembled molecules and a method for analyzing the coverage of the self-assembled molecules in nanowire and nanochannel patterned on solid surface, solid surface, or bulk solid surface by using the nanoparticles. According to the method, the presence of specific functional groups of self-assembled molecules and the degree of reaction can be analyzed by introducing nanoparticles to a biomaterial immobilization substrate including self-assembled molecules and measuring the number of gold nanoparticles existing on the surface.

Abstract: Provided are a biosensor using a silicon nanowire and a method of manufacturing the same. The silicon nanowire can be formed to have a shape, in which identical patterns are continuously repeated, to enlarge an area in which probe molecules are fixed to the silicon nanowire, thereby increasing detection sensitivity. In addition, the detection sensitivity can be easily adjusted by adjusting a gap between the identical patterns of the silicon nanowire depending on characteristics of target molecules, without adjusting a line width of the silicon nanowire in the conventional art. Further, the gap between the identical patterns of the silicon nanowire can be adjusted depending on characteristics of the target molecule to differentiate detection sensitivities, thereby simultaneously detecting various detection sensitivities.

Abstract: Provided are a biosensor with a silicon nanowire and a method of manufacturing the same, and more particularly, a biosensor with a silicon nanowire including a defect region formed by irradiation of an electron beam, and a method of manufacturing the same. The biosensor includes: a silicon substrate; a source region disposed on the silicon substrate; a drain region disposed on the silicon substrate; and a silicon nanowire disposed on the source region and the drain region, and having a defect region formed by irradiation of an electron beam. Therefore, by irradiating a certain region of a high-concentration doped silicon nanowire with an electron beam to lower electron mobility in the certain region, it is possible to maintain a low contact resistance between the silicon nanowire and a metal electrode and to lower operation current of a biomaterial detection part, thereby improving sensitivity of the biosensor.

Abstract: Provided are a semiconductor Field-Effect Transistor (FET) sensor and a method of fabricating the same. The method includes providing a semiconductor substrate, forming a sensor structure having a fin-shaped structure on the semiconductor substrate, injecting ions for electrical ohmic contact into the sensor structure, and depositing a metal electrode on the sensor structure, immobilizing a sensing material to be specifically combined with a target material onto both sidewall surfaces of the fin-shaped structure, and forming a passage on the sensor structure such that the target material passes through the fin-shaped structure.

Abstract: Provided is a method of manufacturing a nano size-gap electrode device. The method includes the steps of: disposing a floated nano structure on a semiconductor layer; forming a mask layer having at least one opening pattern to intersect the nano structure; and depositing a metal on the semiconductor layer exposed through the opening pattern to form an electrode, such that a nano size-gap is provided under the nano structure by the nano structure.

Abstract: Provided is a method of manufacturing a semiconductor device in which properties of photoresist through a lithography process are changed to form a dummy structure, and the structure is applied to a process of forming a gate electrode.

Abstract: A tri-gated molecular field effect transistor includes a gate electrode formed on a substrate and having grooves in a source region, a drain region and a channel region, and at least one molecule inserted between the source and drain electrodes in the channel region. The effects of the gate voltage on electrons passing through the channel can be maximized, and a variation gain of current supplied between the source and drain electrodes relative to the gate voltage can be greatly increased. Thus, a molecular electronic circuit having high functionality and reliability can be obtained.

Abstract: Provided is a method for manufacturing a nano-gap electrode device comprising the steps of: forming a first electrode on a substrate; forming a spacer on a sidewall of the first electrode; forming a second electrode on an exposed substrate at a side of the spacer; and forming a nano-gap between the first electrode and the second electrode by removing the spacer, whereby it is possible to control the nano-gap position, width, shape, and etc., reproducibly, and manufacture a plurality of nano-gap electrode devices at the same time.

Abstract: An organic semiconductor device and a method of fabricating the same are provided. The device includes: a first electrode; an electron channel layer formed on the first electrode; and a second electrode formed on the electron channel layer, wherein the electron channel layer comprises: a lower organic layer formed on the first electrode; a nano-particle layer formed on the lower organic layer and including predetermined sizes of nano-particles that are spaced a predetermined distance apart from each other; and an upper organic layer formed over the nano-particle layer. Accordingly, a highly integrated organic semiconductor device can be fabricated by a simple fabrication process, and nonuniformity of devices due to threshold voltage characteristics and downsizing of the device can resolved, so that a semiconductor device having excellent performance can be implemented.

Abstract: A memory device including a dielectric thin film having a plurality of dielectric layers and a method of manufacturing the same are provided. The memory device includes: a bottom electrode; at least one dielectric thin film disposed on the bottom electrode and having a plurality of dielectric layers with different charge trap densities from each other; and an top electrode disposed on the dielectric thin film. Therefore, a memory device, which can be readily manufactured by a simple process and can be highly integrated using its simple structure, can be provided.

Abstract: Provided is a method of manufacturing a nano size-gap electrode device. The method includes the steps of: disposing a floated nano structure on a semiconductor layer; forming a mask layer having at least one opening pattern to intersect the nano structure; and depositing a metal on the semiconductor layer exposed through the opening pattern to form an electrode, such that a nano size-gap is provided under the nano structure by the nano structure.

Abstract: Provided is a method for manufacturing a nano-gap electrode device comprising the steps of: forming a first electrode on a substrate; forming a spacer on a sidewall of the first electrode; forming a second electrode on an exposed substrate at a side of the spacer; and forming a nano-gap between the first electrode and the second electrode by removing the spacer, whereby it is possible to control the nano-gap position, width, shape, and etc., reproducibly, and manufacture a plurality of nano-gap electrode devices at the same time.

Abstract: Provided are a nanowire sensor and a method of manufacturing the same. The nanowire sensor includes: a sensing target system comprising a target element to be detected; two electrodes separated from each other contained in the sensing target system; vanadium oxide (V2O5) nanowires incorporated in the sensing target system and attached to the two electrodes; and a measuring unit for measuring a change in resistance of the nanowires as the nanowires detect the target element.

Abstract: Provided is a tri-gated molecular field effect transistor (FET) and a method of fabricating the same. The tri-gated molecular field effect transistor includes a gate electrode formed on a substrate and having grooves in a source region, a drain region and a channel region, and at least one molecule inserted between the source and drain electrodes in the channel region. The effects of the gate voltage on electrons passing through the channel can be maximized, and a variation gain of current supplied between the source and drain electrodes relative to the gate voltage can be greatly increased. Thus, a molecular electronic circuit having high functionality and reliability can be obtained.