Abstract: Example embodiment non-volatile memory devices may be capable of increased integration and reliability and may provide example methods of operating non-volatile memory devices. Example embodiment non-volatile memory devices may include a first control gate electrode on a semiconductor substrate. A first charge storing layer may be between the semiconductor substrate and the first control gate electrode. A source region may be defined in the semiconductor substrate at one side of the first control gate electrode. A first auxiliary gate electrode may be at the other side of the first control gate electrode and may be recessed into the semiconductor substrate. A first drain region may be defined in the semiconductor substrate at one side of the first auxiliary gate electrode opposite to the first control gate electrode. A bit line may be connected to the first drain region.

Abstract: Example embodiments relate to a semiconductor device including a fin-type channel region and a method of fabricating the same. The semiconductor device includes a semiconductor substrate, a semiconductor pillar and a contact plug. The semiconductor substrate includes at least one pair of fins used (or functioning) as an active region. The semiconductor pillar may be interposed between portions of the fins to connect the fins. The contact plug may be disposed (or formed) on the semiconductor pillar and electrically connected to top surfaces of the fins.

Abstract: A nonvolatile memory device having lower bit line contact resistance and a method of fabricating the same is provided. In the nonvolatile memory device, a semiconductor substrate of a first conductivity type may include first and second fins. A common bit line electrode may connect one end of the first fin to one end of the second fin. A plurality of control gate electrodes may cover the first and second fins and expand across the top surface of each of the first and second fins. A first string selection gate electrode may be positioned between the common bit line electrode and the plurality of control gate electrodes. The first string selection gate electrode may cover the first and second fins and expand across the top surface of each of the first and second fins. A second string selection gate electrode may be positioned between the first string selection gate electrode and the plurality of control gate electrodes.

Abstract: Provided are example embodiments of a non-volatile memory device and a method of fabricating the same. The non-volatile memory device may include a control gate electrode arranged on a semiconductor substrate, a gate insulating layer interposed between the semiconductor substrate and the control gate electrode, a storage node layer interposed between the gate insulating layer and the control gate electrode, a blocking insulating layer interposed between the storage node layer and the control gate electrode, first dopant doping regions along a first side of the control gate electrode, and second dopant doping regions along a second side of the control gate electrode. The first dopant doping regions may alternate with the second dopant doping regions. Stated differently, each of the second dopant doping regions may be arranged in a region on the second side of the control gate electrode that is adjacent to one of the first dopant doping regions.

Abstract: A non-volatile memory device and a method of fabricating the same are provided. In the non-volatile memory device, at least one first semiconductor layer of a first conductivity type may be formed spaced apart from each other on a portion of a substrate. A plurality of first resistance variation storage layers may contact first sidewalls of each of the at least one first semiconductor layer. A plurality of second semiconductor layers of a second conductivity type, opposite to the first conductivity type, may be interposed between the first sidewalls of each of the at least one first semiconductor layer and the plurality of first resistance variation storage layers. A plurality of bit line electrodes may be connected to each of the plurality of first resistance variation storage layers.

Abstract: A wire grid polarizer and a method of manufacturing the wire grid polarizer are provided. The wire grid polarizer includes: a substrate; and a plurality of core-shell nano wires arranged on the substrate and including wire cores and polymer shells enclosing the wire cores to a predetermined thickness.

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: A capacitor of a memory device, and a method of fabricating the same, includes a lower electrode electrically coupled to a doping region of a transistor structure, the lower electrode having a metal electrode and a metal oxide electrode, a ferroelectric layer covering and extending laterally along the lower electrode, and an upper electrode formed on the ferroelectric layer.

Abstract: Example embodiments provide a non-volatile memory device with increased integration and methods of operating and fabricating the same. A non-volatile memory device may include a plurality of first storage node films and a plurality of first control gate electrodes on a semiconductor substrate. A plurality of second storage node films and a plurality of second control gate electrodes may be recessed into the semiconductor substrate between two adjacent first control gate electrodes and below the bottom of the plurality of first control gate electrodes. A plurality of bit line regions may be on the semiconductor substrate and each may extend across the plurality of first control gate electrodes and the plurality of second control gate electrodes.

Abstract: Unit cells of a non-volatile memory device and a method thereof are provided. In an example, the unit cell may include a first memory transistor and a second memory transistor connected to each other in series and further connected in common to a word line, the first and second memory transistors including first and second storage nodes, respectively, the first and second storage nodes configured to execute concurrent memory operations. In another example, the unit cell may include a semiconductor substrate in which first and second bit line regions are defined.

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: A semiconductor memory device includes a semiconductor substrate, a control gate electrode recessed in the semiconductor substrate, a storage node layer interposed between a sidewall of the control gate electrode and the semiconductor substrate, a tunneling insulation layer interposed between the storage node layer and the semiconductor substrate, a blocking insulation layer interposed between the storage node layer and the control gate electrode, and first and second channel regions formed around a surface of the semiconductor substrate to at least partially surround the control gate electrode. The semiconductor memory device may include a plurality of control gate electrodes, storage node layers, tunneling insulation layers, blocking insulation layers, and continuous first and second channel regions.

Abstract: A liquid coating apparatus and method for spraying a liquid on a wafer. The liquid coating apparatus may include a nozzle unit spraying the liquid on the wafer and moving relative to the wafer and a laminar flow forming unit forming a forced air flow around the nozzle unit. Though a wake may be formed around the nozzle unit by a movement of the nozzle unit, the laminar forming unit may reduce and/or minimize an influence of the wake.

Abstract: A method of forming a nano-particle array by convective assembly and a convective assembly apparatus for the same are provided. The method of forming nano-particle array comprises: coating a plurality of nano-particles by forming a coating layer; performing a first convective assembly by moving a first substrate facing, in parallel to and spaced apart from a second substrate at a desired distance such that a colloidal solution including the coated nano-particles is between the first and second substrate; and performing a second convective assembly for evaporating a solvent by locally heating a surface of the colloidal solution drawn when the first substrate is moved in parallel relative to the second substrate. The present invention provides the method of forming the nano-particle array where nano-particles having a particle size from a few to several tens of nanometers are uniformly arrayed on a large area substrate at a low cost, and the convective assembly apparatus for the same.

Abstract: A capacitor of a memory device, and a method of fabricating the same, includes a lower electrode electrically coupled to a doping region of a transistor structure, the lower electrode having a metal electrode and a metal oxide electrode, a ferroelectric layer covering and extending laterally along the lower electrode, and an upper electrode formed on the ferroelectric layer.

Abstract: A method of forming carbon fibers at a low temperature below 450° C. using an organic-metal evaporation method is provided. The method includes: heating a substrate and maintaining the substrate at a temperature of 200 to 450° C. after loading the substrate into a reaction chamber; preparing an organic-metal compound containing Ni; forming an organic-metal compound vapor by vaporizing the organic-metal compound; and forming carbon fibers on the substrate by facilitating a chemical reaction between the organic-metal compound vapor and a reaction gas containing ozone in the reaction chamber.

Abstract: Example embodiments relate to a method of manufacturing amorphous NiO thin films and nonvolatile memory devices including amorphous thin films that use a resistance material. Other example embodiments relate to a method of manufacturing amorphous NiO thin films having improved switching and resistance characteristics by reducing a leakage current and non-volatile memory devices using an amorphous NiO thin film. Provided is a method of manufacturing an amorphous NiO thin film having improved switching behavior by reducing leakage current and improving resistance characteristics. The method may include preparing a substrate in a vacuum chamber, preparing a nickel precursor material, preparing a source gas by vaporizing the nickel precursor material, preparing a reaction gas, preparing a purge gas and forming a monolayer NiO thin film on the substrate by performing one cycle of sequentially supplying the source gas, the purge gas, the reaction gas and the purge gas into the vacuum chamber.

Abstract: A ferroelectric capacitor having a three-dimensional structure, a nonvolatile memory device having the same, and a method of fabricating the same are provided. The ferroelectric capacitor may include a trench-type lower electrode, at least one layer formed around the lower electrode, a ferroelectric layer (PZT layer) formed on the lower electrode and the at least one layer and an upper electrode formed on the ferroelectric layer. The at least one layer may be at least one insulating interlayer and the at least one layer may also be at least one diffusion barrier layer. The at least one layer may be formed of an insulating material excluding SiO2 or may have a perovskite crystal structure excluding Pb.

Abstract: Provided is a method for manufacturing a material layer capable of increasing the deposition rate of a noble metal layer on a ferroelectric layer, a method for manufacturing a ferroelectric capacitor using the same, a ferroelectric capacitor manufactured by the same method, and a semiconductor memory device having the ferroelectric capacitor and a manufacturing method thereof. According to a method for manufacturing the material layer, a ferroelectric layer is formed. The ferroelectric layer may be exposed to seed plasma, and a material layer including a source material of the seed plasma may be formed on a region of the ferroelectric layer exposed to the seed plasma.

Abstract: Embodiments are provided of a duplex chemical vapor deposition (CVD) system and pulsed processing method using the same. The duplex CVD system may include first and second process chambers, one or more reactive sources, and reactive source suppliers that correspond to the reactive sources, respectively. The reactive source suppliers may include a first conduit portion connected to the respective reactive sources, a second conduit portion having one terminal connected to the first conduit portion and the other terminal connected to the first process chamber, and a third conduit portion having one terminal connected to the first conduit portion and the other terminal connected to the second process chamber.