Abstract: Example embodiments relate to a method of forming a core-shell structure. According to a method, a region in which the core-shell structure will be formed is defined on a substrate, and a core and a shell layer may be sequentially stacked in the defined region. A first shell layer may further be formed between the substrate and the core. When the core and the shell layer are sequentially stacked in the core-shell region, the method may further include forming a groove on the substrate, forming the first shell layer covering surfaces of the groove, forming the core in the groove of which surfaces are covered by the first shell layer, and forming a second shell layer covering the core.

Abstract: A quantum interference transistor may include a source; a drain; N channels (N?2), between the source and the drain, and having N?1 path differences between the source and the drain; and at least one gate disposed at one or more of the N channels. One or more of the N channels may be formed in a graphene sheet. A method of manufacturing the quantum interference transistor may include forming one or more of the N channels using a graphene sheet. A method of operating the quantum interference transistor may include applying a voltage to the at least one gate. The voltage may shift a phase of a wave of electrons passing through a channel at which the at least one gate is disposed.

Abstract: Provided is a chemical sensor that may include a first electrode on a substrate, a sensing member covering the first electrode on the substrate, and a plurality of second electrodes on a surface of the sensing member exposing the surface of the sensing member. The chemical sensor may be configured to measure the change in electrical characteristics when a compound to be sensed is adsorbed on the sensing member. Provided also is a chemical sensor array including an array of chemical sensors.

Abstract: A luminous device and a method of manufacturing the luminous device are provided. The luminous device includes a light emitting layer and first and second electrodes connected to the light emitting layer. The light emitting layer is a strained nanowire.

Abstract: A spin field effect transistor may include at least one gate electrode, a channel layer, a first stack and a second stack separate from each other on a substrate, wherein the channel layer is formed of a half metal. The half metal may be at least one material selected from the group consisting of chrome oxide (CrO2), magnetite (Fe3O4), a double perovskite structure material, a Heusler alloy, NiMnSb, La(1-x)AxMnO3 (A=Ca, Ba, Sr, x˜0.3), and GaN doped with Cu, and the double perovskite structure material is expressed as a chemical composition of A2BB?O6, and a material corresponding to A is Ca, Sr, or Ba, a material corresponding to B is a 3d orbital transition metal, and a material corresponding to B? is a 4d orbital transition metal. The 3d orbital transition metal may be Fe or Co, and the 4d orbital transition metal is Mo or Re.

Abstract: A capacitorless DRAM and methods of manufacturing and operating the same are provided. The capacitorless DRAM includes a source, a drain and a channel layer, formed on a substrate. A charge reserving layer is formed on the channel layer. The capacitorless DRAM includes a gate that contacts the channel layer and the charge reserving layer.

Abstract: Provided is a method of reliably operating a highly integratable nonvolatile memory device. The nonvolatile memory device may include a string selection transistor, a plurality of memory transistors, and a ground selection transistor between a bit line and a common source line. In the nonvolatile memory device, data may be erased from the memory transistors by applying an erasing voltage to the bit line or the common source line.

Abstract: A luminous device and a method of manufacturing the luminous device are provided. The luminous device includes a light emitting layer and first and second electrodes connected to the light emitting layer. The light emitting layer is a strained nanowire.

Abstract: Example embodiments include nonvolatile memory devices that have good operation performance and may be made in a highly integrated structure, and methods of operating the same. Example embodiments of the nonvolatile memory devices include a substrate electrode, and a semiconductor channel layer on the substrate electrode, a floating gate electrode on the substrate electrode, wherein a portion of the floating gate electrode faces the semiconductor channel layer, a control gate electrode on the floating gate electrode, and wherein a distance between a portion of the floating gate electrode and the substrate electrode is smaller than a distance between the semiconductor channel layer and the substrate electrode wherein charge tunneling occurs.

Abstract: Provided are a capacitorless DRAM and methods of manufacturing the same. The capacitorless DRAM may include a substrate including a source, a drain and a channel, a gate on the channel of the substrate, and a hole reserving unit below the channel.

Abstract: Provided are a light emitting diode (LED) using a Si nanowire as an emission device and a method of fabricating the same. The LED includes: a semiconductor substrate; first and second semiconductor protrusions disposed on the semiconductor substrate to face each other; a semiconductor nanowire suspended between the first and second semiconductor protrusions; and first and second electrodes disposed on the first and second protrusions, respectively.

Abstract: A semiconductor memory device performing an erase operation using an erase gate and a method of manufacturing the same are provided. The memory device may include a charge trap layer storing a first charge transfer medium having a first polarity and at least one erase gate. The at least one erase gate may be formed below the charge trap layer. A second charge transfer medium, which has a second polarity opposite to the first polarity, may be stored in the at least one erase gate. During the erase operation, the second charge transfer medium migrates to the charge trap layer causing the first charge transfer medium to combine with the second charge transfer medium.

Abstract: Provided are a nonvolatile memory device and a method of operating the same, which have increased operation reliability and which facilitate increased integration. The nonvolatile memory device may include a semiconductor substrate, and at least one charge storage layer may be provided on a semiconductor substrate. At least one control gate electrode may be provided on the at least one charge storage layer. At least one first auxiliary gate electrode may be disposed on one side of and apart from the at least one charge storage layer and isolated from the semiconductor substrate.

Abstract: Provided is a memory device comprising a molecular adsorption layer. The memory device includes: a substrate; a source electrode and a drain electrode formed on the substrate and separated from each other; a carbon nanotube (CNT) layer electrically connected to the source electrode and the drain electrode; a memory cell contacting the CNT so as to store a charge from the CNT; and a gate electrode formed on the memory cell, wherein the memory cell comprises: a first insulating layer formed on the CNT; a molecular adsorption layer which is formed on the first insulating layer and acts as a charge storage layer; and a second insulating layer formed on the molecular adsorption layer.

Abstract: Provided is a memory device comprising a molecular adsorption layer. The memory device includes: a substrate; a source electrode and a drain electrode formed on the substrate and separated from each other; a carbon nanotube (CNT) layer electrically connected to the source electrode and the drain electrode; a memory cell contacting the CNT so as to store a charge from the CNT; and a gate electrode formed on the memory cell, wherein the memory cell comprises: a first insulating layer formed on the CNT; a molecular adsorption layer which is formed on the first insulating layer and acts as a charge storage layer; and a second insulating layer formed on the molecular adsorption layer.