Abstract: Provided is a semiconductor device that comprises a metal gate having a low sheet resistance characteristic and a high diffusion barrier characteristic and a method of fabricating the metal gate of the semiconductor device. The semiconductor device includes a metal gate formed on a gate insulating film, wherein the metal gate is formed of a metal nitride that contains Al or Si and includes upper and lower portions where the content of Al or Si is relatively high and a central portion where the content of Al or Si is relatively low.

Abstract: Provided are a phase change layer and a method of forming the phase change layer and a phase change memory device including the phase change layer, and methods of manufacturing and operating the phase change memory device. The phase change layer may be formed of a quaternary compound including an amount of indium (In) ranging from about 15 at. % to about 20 at. %. The phase change layer may be InaGebSbcTed, wherein an amount of germanium (Ge) ranges from about 10 at. %?b?about 15 at. %, an amount of antimony (Sb) ranges from about 20 at. %?c?about 25 at. %, and an amount of tellurium (Te) ranges from about 40 at. %?d?about 55 at. %.

Abstract: Insulating impurities may be uniformly distributed over an entire or partial region of the phase change material. The PRAM may include a phase change layer including the phase change material. The insulating impurity content of the phase change material may be 0.1 to 10% (inclusive) the volume of the phase change material. The insulating impurity content of the phase change material may be adjusted by controlling the power applied to a target including the insulating impurities.

Abstract: Provided is a method of fabricating a Schottky barrier transistor. The method includes (a) forming a pair of cavities for forming a source forming portion and a drain forming portion having a predetermined depth and parallel to each other and a channel forming portion having a fin shape between the cavities in a substrate; (b) filling the pair of cavities with a metal; (c) forming a channel, a source, and a drain by patterning the channel forming portion, the source forming portion, and the drain forming portion in a direction perpendicular to a lengthwise direction of the channel forming portion; (d) sequentially forming a gate oxide layer and a gate metal layer that cover the channel, the source, and the drain on the substrate; and (e) forming a gate electrode corresponding to the channel by patterning the gate metal layer, wherein one of the operations (b) through (e) further comprises forming a Schottky barrier by annealing the substrate.

Abstract: A PRAM and a fabricating method thereof are provided. The PRAM includes a transistor and a data storage capability. The data storage capability is connected to the transistor. The data storage includes a top electrode, a bottom electrode, and a porous PCM layer. The porous PCM layer is interposed between the top electrode and the bottom electrode.

Abstract: In a memory device, a transistor may be formed on a substrate, and a first electrode may be electrically connected thereto. A phase change material film may be vertically formed on the first electrode, and a second electrode may be formed on the phase change material film.

Abstract: Provided is a method of operating a phase change random access memory comprising a switching device and a storage node comprising a phase change layer. The method includes applying a reset current passing through the phase change layer from a lower portion of the phase change layer toward an upper portion of the phase change layer and being smaller than 1.6 mA to the storage node to change a portion of the phase change layer into an amorphous state. The set voltage is in an opposite direction is exemplary embodiments, and a connector is of small cross-sectional area.

Abstract: Provided are a phase change layer and a method of forming the phase change layer and a phase change memory device including the phase change layer, and methods of manufacturing and operating the phase change memory device. The phase change layer may be formed of a quaternary compound including an amount of indium (In) ranging from about 15 at. % to about 20 at. %. The phase change layer may be InaGebSbcTed, wherein an amount of germanium (Ge) ranges from about 10 at. %?b?about 15 at. %, an amount of antimony (Sb) ranges from about 20 at. %?c?about 25 at. %, and an amount of tellurium (Te) ranges from about 40 at. %?d?about 55 at. %.

Abstract: Provided is a semiconductor device and a method of fabricating a metal gate in the semiconductor device. The semiconductor device includes a metal gate formed on a gate insulating film, the metal gate is formed of a mixture of a metal nitride and a metal carbide, and a work function of the metal gate is determined according to ratios of the metal nitride with respect to the metal carbide.

Abstract: Provided are a phase change layer and a method of forming the phase change layer and a phase change memory device including the phase change layer, and methods of manufacturing and operating the phase change memory device. The phase change layer may be formed of a quaternary compound including an amount of indium (In) ranging from about 15 at. % to about 20 at. %. The phase change layer may be InaGebSbcTed, wherein an amount of germanium (Ge) ranges from about 10 at. %?b?about 15 at. %, an amount of antimony (Sb) ranges from about 20 at. %?c?about 25 at. %, and an amount of tellurium (Te) ranges from about 40 at. %?d?about 55 at. %.

Abstract: Provided is a method of fabricating a Schottky barrier transistor. The method includes (a) forming a pair of cavities for forming a source forming portion and a drain forming portion having a predetermined depth and parallel to each other and a channel forming portion having a fin shape between the cavities in a substrate; (b) filling the pair of cavities with a metal; (c) forming a channel, a source, and a drain by patterning the channel forming portion, the source forming portion, and the drain forming portion in a direction perpendicular to a lengthwise direction of the channel forming portion; (d) sequentially forming a gate oxide layer and a gate metal layer that cover the channel, the source, and the drain on the substrate; and (e) forming a gate electrode corresponding to the channel by patterning the gate metal layer, wherein one of the operations (b) through (e) further comprises forming a Schottky barrier by annealing the substrate.

Abstract: Provided is a method of fabricating a Schottky barrier transistor. The method includes (a) forming a pair of cavities for forming a source forming portion and a drain forming portion having a predetermined depth and parallel to each other and a channel forming portion having a fin shape between the cavities in a substrate; (b) filling the pair of cavities with a metal; (c) forming a channel, a source, and a drain by patterning the channel forming portion, the source forming portion, and the drain forming portion in a direction perpendicular to a lengthwise direction of the channel forming portion; (d) sequentially forming a gate oxide layer and a gate metal layer that cover the channel, the source, and the drain on the substrate; and (e) forming a gate electrode corresponding to the channel by patterning the gate metal layer, wherein one of the operations (b) through (e) further comprises forming a Schottky barrier by annealing the substrate.

Abstract: A phase change random access memory (PRAM), and a method of operating the PRAM are provided. In the PRAM comprising a switching element and a storage node connected to the switching element, the storage node comprises a first electrode, a second electrode, a phase change layer between the first electrode and a second electrode, and a heat efficiency improving element formed between the first electrode and the phase change layer. The heat efficiency improving element may be one of a carbon nanotube (CNT) layer, a nanoparticle layer, and a nanodot layer, and the nanoparticle layer may be a fullerene layer.

Abstract: A programming method for a phase-change random access memory (PRAM) may be provided. The programming method may include determining an amorphous state of a chalcogenide material using programming pulses to form programming areas having threshold voltages corresponding to logic high and logic low, and/or controlling a trailing edge of programming pulses during programming to control a quenching speed of the chalcogenide material so as to adjust a threshold voltage of the chalcogenide material. Accordingly, programming pulses corresponding to logic low or logic high may have uniform magnitudes regardless of a corresponding logic level. Accordingly, reliability of a PRAM device may be improved.

Abstract: In a memory device, a transistor may be formed on a substrate, and a first electrode may be electrically connected thereto. A phase change material film may be vertically formed on the first electrode, and a second electrode may be formed on the phase change material film.

Abstract: Example embodiments may provide a doped phase change layer and a method of operating and fabricating a phase change memory with the example embodiment doped phase change layer. The phase change memory may include a storage node having a phase change layer and a switching device, wherein the phase change layer includes indium with a concentration ranging from about 5 at % to about 15 at %. The phase change layer may be a GST layer that includes indium. The phase change layer may be a GST layer that includes gallium.

Abstract: In a memory device, a transistor may be formed on a substrate, and a first electrode may be electrically connected thereto. A phase change material film may be vertically formed on the first electrode, and a second electrode may be formed on the phase change material film.

Abstract: A PRAM and a fabricating method thereof are provided. The PRAM includes a transistor and a data storage capability. The data storage capability is connected to the transistor. The data storage includes a top electrode, a bottom electrode, and a porous PCM layer. The porous PCM layer is interposed between the top electrode and the bottom electrode.

Abstract: A method of fabricating a phase change RAM (PRAM) having a fullerene layer is provided. The method of fabricating the PRAM may include forming a bottom electrode, forming an interlayer dielectric film covering the bottom electrode, and forming a bottom electrode contact hole exposing a portion of the bottom electrode in the interlayer dielectric film, forming a bottom electrode contact plug by filling the bottom electrode contact hole with a plug material, forming a fullerene layer on a region including at least an upper surface of the bottom electrode contact plug and sequentially stacking a phase change layer and an upper electrode on the fullerene layer. The method may further include forming a switching device on a substrate and a bottom electrode connected to the switching device, forming an interlayer dielectric film covering the bottom electrode and forming a bottom electrode contact hole exposing a portion of the bottom electrode in the interlayer dielectric film.

Abstract: A phase change memory device includes a switch and a storage node connected to the switch. The storage node includes a first electrode, a phase change layer and a second electrode. The phase change layer is formed of an InSbTe compound doped with Ge. In a method of operating a phase change memory including a switch and a storage node, the switch is maintained in an on state, and a first current is applied to the storage node.