Abstract: Semiconductor apparatuses having optical connections between a memory controller and a memory module are provided. A semiconductor apparatus includes a memory controller, at least one socket configured to receive a memory module, and a first optical-electrical module. A second optical-electrical module is mounted in the socket and optically coupled to the first optical-electrical module via at least one optical channel.

Abstract: Provided is an image sensor using a photo-detecting molecule and a method of operating the image sensor. The image sensor may include a plurality of first electrodes disposed parallel to each other and a plurality of second electrodes disposed parallel to each other in a direction perpendicular to the first electrodes and above the first electrodes, and a plurality of subpixels formed in regions where the first electrodes cross the second electrodes. Each of the subpixels may comprise a photo-detecting molecule layer that may generate charges by absorbing light having a certain wavelength, a charge generation layer that may form a plurality of secondary electrons by receiving the charges from the photo-detecting molecule layer when a known voltage is applied between the first electrodes and the second electrodes, and a variable resistance layer, an electrical state of which is changed by receiving the secondary electrons generated from the charge generation layer.

Abstract: A distance measuring sensor may include: a photoelectric conversion region; first and second charge storage regions; first and second trenches; and/or first and second vertical photogates. The photoelectric conversion region may be in a substrate and/or may be doped with a first impurity in order to generate charges in response to received light. The first and second charge storage regions may be in the substrate and/or may be doped with a second impurity in order to collect charges. The first and second trenches may be formed to have depths in the substrate that correspond to the first and second charge storage regions, respectively. The first and second vertical photogates may be respectively in the first and second trenches. A three-dimensional color image sensor may include a plurality of unit pixels. Each unit pixel may include a plurality of color pixels and the distance measuring sensor.

Abstract: A non-volatile memory device and a method of fabricating the same are provided. A non-volatile memory device may include a semiconductor substrate including a body and at least one pair of fins vertically protruding from the body and spaced apart from each other, and at least one control gate electrode on at least portions of outer side surfaces of the at least one pair of fins and extending onto top portions of the at least one pair of fins on an angle with the at least one pair of fins. The non-volatile memory device may further include at least one pair of gate insulating layers between the at least one control gate electrode and the at least one pair of fins, and at least one pair of storage node layers between the at least one pair of gate insulating layers and at least a portion of the at least one control gate electrode. The at least one control gate electrode may extend onto top portions of the at least one pair of fins in a zigzag fashion.

Abstract: The non-volatile memory device may include a semiconductor substrate having a body and a pair of fins. A bridge insulating layer may non-electrically connect upper portions of the pair of fins to define a void between the pair of fins. Outer surfaces of the pair of fins are the surfaces of the pair of fins that do not face the void and inner surfaces of the pair of fins are the surfaces of the pair of fins that do face the void. The non-volatile memory device may further include at least one control gate electrode that may cover at least a portion of outer surfaces of the pair of fins, may extend over the bridge insulating layer, and may be isolated from the semiconductor substrate. At least one pair of gate insulating layers may be between the at least one control gate electrode and the pair of fins, and at least one pair of storage nodes may be between the at least one pair of gate insulating layers and the at least one control gate electrode.

Abstract: An optical amplifying medium, a method of manufacturing the optical amplifying medium are provided, and an optical device comprising the optical amplifying medium. The optical amplifying medium includes a multi-layer structure in which a first material layer doped with an activator and a second material layer that comprises a sensitizer are stacked.

Abstract: Provided are a distance measuring sensor including a double transfer gate, and a three dimensional color image sensor including the distance measuring sensor. The distance measuring sensor may include first and second charge storage regions which are spaced apart from each other on a substrate doped with a first impurity, the first and second charge storage regions being doped with a second impurity; a photoelectric conversion region between the first and second charge storage regions on the substrate, being doped with the second impurity, and generating photo-charges by receiving light; and first and second transfer gates which are formed between the photoelectric conversion region and the first and second charge storage regions above the substrate to selectively transfer the photo-charges in the photoelectric conversion region to the first and second charge storage regions.

Abstract: A semiconductor memory device with a dual storage node structure as well as methods of fabricating and operating such a device are provided. The semiconductor memory device includes a substrate, a first transistor formed on the substrate, a first storage node connected to a source region of the first transistor, a second storage node connected to a drain region of the first transistor, and a plate line commonly contacting the first storage node and the second storage node.

Abstract: Provided are a non-volatile memory device that may be configured in a stacked structure and may be more easily highly integrated, and a method of fabricating the non-volatile memory device. At least one first electrode and at least one second electrode are provided. The at least one second electrode may cross the at least one first electrode. At least one data storage layer may be at an intersection between the at least one first electrode and the at least one second electrode. Any one of the at least one first electrode and the at least one second electrode may include at least one junction diode connected to the at least one data storage layer.

Abstract: Example embodiments relate to a semiconductor device and a method of manufacturing the same. A semiconductor device according to example embodiments may have reduced disturbances during reading operations and a reduced short channel effect. The semiconductor device may include a semiconductor substrate having a body and a pair of fins protruding from the body. Inner spacer insulating layers may be formed on an upper portion of an inner sidewall of the pair of fins so as to reduce the entrance to the region between the pair of fins. A gate electrode may cover a portion of the external sidewalls of the pair of fins and may extend across the inner spacer insulating layers so as to define a void between the pair of fins. Gate insulating layers may be interposed between the gate electrode and the pair of fins.

Abstract: An image sensor includes a plurality of unit pixels arranged in an array. Each unit pixel includes a plurality of sub-pixels configured to be irradiated by light having the same wavelength. Each sub-pixel includes a plurality of floating body transistors. Each floating body transistor includes a source region, a drain region, a floating body region between the source region and the drain region, and a gate electrode formed on the floating body region.

Abstract: A multi-layered non-volatile memory device and a method of manufacturing the same. The non-volatile memory device may include a plurality of first semiconductor layers having a stack structure. A plurality of control gate electrodes may extend across the first semiconductor layers. A first body contact layer may extend across the first semiconductor layers. A plurality of charge storage layers may be interposed between the control gate electrodes and the first semiconductor layers.

Abstract: Provided is a method and device for reducing lateral movement of charges. The method may include pre-programming at least one memory cell that is in an erased state by applying a pre-programming voltage to the at least one memory cell to have a narrower distribution of threshold voltages than the at least one erased state memory cell and verifying that the pre-programmed memory cell is in the pre-programmed state using a negative effective verifying voltage.

Abstract: A distance measuring sensor may include: a photoelectric conversion region; first and second charge storage regions; first and second trenches; and/or first and second vertical photogates. The photoelectric conversion region may be in a substrate and/or may be doped with a first impurity in order to generate charges in response to received light. The first and second charge storage regions may be in the substrate and/or may be doped with a second impurity in order to collect charges. The first and second trenches may be formed to have depths in the substrate that correspond to the first and second charge storage regions, respectively. The first and second vertical photogates may be respectively in the first and second trenches. A three-dimensional color image sensor may include a plurality of unit pixels. Each unit pixel may include a plurality of color pixels and the distance measuring sensor.

Abstract: Example embodiments provide a method for programming a resistive memory device that includes a resistance conversion layer. The method may include applying multiple pulses to the resistance conversion layer. The multiple pulses may include at least two pulses, where a magnitude of each pulse of the at least two pulses is the same. A first pulse of the at least two pulses may be applied on one side of the resistance conversion layer and a second pulse of the at least two pulses may be applied on the other side of the resistance conversion layer. The applying step may be performed during a set programming operation or a reset programming operation. A resistive memory device for programming a resistance conversion layer may include a first and second electrode, a lower structure, and the resistance conversion layer coupled between the first and second electrodes.

Abstract: A method of fabricating a non-volatile memory device according to example embodiments may include forming a semiconductor layer on a substrate. A plurality of lower charge storing layers may be formed on a bottom surface of the semiconductor layer. A plurality of lower control gate electrodes may be formed on the plurality of lower charge storing layers. A plurality of upper charge storing layers may be formed on a top surface of the semiconductor layer. A plurality of upper control gate electrodes may be formed on the plurality of upper charge storing layers, wherein the plurality of lower and upper control gate electrodes may be arranged alternately.

Abstract: Semiconductor substrates and methods of manufacturing the same are provided. The semiconductor substrates include a substrate region, an insulation region and a floating body region. The insulation region is disposed on the substrate region. The floating body region is separated from the substrate region by the insulation region and is disposed on the insulation region. The substrate region and the floating body region are formed of materials having identical characteristics. The method of manufacturing the semiconductor substrate including forming at least one floating body pattern by etching a bulk substrate, separating the bulk substrate into a substrate region and a floating body region by etching a lower middle portion of the floating body pattern, and filling an insulating material between the floating body region and the substrate region.

Abstract: Semiconductor devices and semiconductor apparatuses including the same are provided. The semiconductor devices include a body region disposed on a semiconductor substrate, gate patterns disposed on the semiconductor substrate and on opposing sides of the body region, and first and second impurity doped regions disposed on an upper surface of the body region. The gate patterns may be separated from the first and second impurity doped regions by, or greater than, a desired distance, such that the gate patterns do not to overlap the first and second impurity doped regions in a direction perpendicular to the first and second impurity doped regions.

Abstract: An information storage device using magnetic domain wall motion and a method of operating the same are provided. The information storage device includes a magnetic track having a plurality of magnetic domains and magnetic domain walls arranged alternately. A current supply unit is configured to apply current to the magnetic track, and a plurality of reading/writing units are arranged on the magnetic track. The information storage device further includes a plurality of storage units. Each of the plurality of storage units is connected to a corresponding one of the plurality of reading/writing units for storing data temporarily.

Abstract: Data storage devices using movement of magnetic domain walls and methods of operating the same are provided. A data storage device includes a magnetic track having a verifying region. Within the verifying region, first and second magnetic domains are arranged alternately. The first magnetic domains correspond to first data and the second magnetic domains correspond to second data. A verification sensor is arranged at an end of the verifying region. A current applying element is configured to apply one or more pulse currents to the magnetic track. A first counter is connected to the verification sensor and configured to count the number of magnetic domains passing through the verification sensor.