Abstract: A phase-change memory device includes a phase-change memory cell having a volume of material which is programmable between amorphous and crystalline states. A write current source selectively applies a first write current pulse to program the phase-change memory cell into the amorphous state and a second write current pulse to program the phase-change memory cell into the crystalline state. The phase-change memory device further includes a restore circuit which selectively applies the first current pulse to the phase-change memory cell to restore at least an amorphous state of the phase-change memory cell.

Abstract: A phase-change memory device may include first and second spaced apart conductive electrodes, and a phase-change memory element coupled between the first and second conductive electrodes. More particularly, a first portion of the phase-change memory element may have a first cross-sectional area along a current path between the first and second conductive electrodes, and a second portion of the phase-change memory element may have a second cross-sectional area along the current path between the first and second conductive electrodes. Moreover, the first and second cross-sectional areas may be different.

Abstract: A phase-changeable memory device comprises a substrate and an access transistor formed in and/or on the substrate. Laterally spaced apart first and second conductive patterns are disposed on the substrate and have opposing sidewalls. A conductor electrically connects the first conductive region to a source/drain region of the access transistor. A phase-changeable material region is disposed between the first and second conductive patterns and contacts the opposing sidewalls of the first and second conductive patterns. Contact areas between the conductive patterns and the phase-changeable material region are preferably substantially smaller than contact areas at which the conductive patterns contact conductors (e.g., vias) connected thereto, such that high current densities may be developed in the phase-changeable material. Methods of fabricating such devices are also discussed.

Abstract: According to some embodiments of the present invention, there are provided PRAMS having a phase-change layer pattern interposed between a molding layer and a forming layer pattern, and methods of forming the same that include a node conductive layer pattern, a molding layer, a forming layer pattern and a protecting layer. The molding layer, the forming layer pattern and the protecting layer are formed to cover the planarized interlayer insulating layer and the node conductive layer pattern. A lower electrode is interposed between the molding layer and the planarized interlayer insulating layer. A phase-change layer pattern is formed on the planarized interlayer insulating layer. A spacer pattern is disposed between the phase-change layer pattern and the molding layer.

Abstract: A phase changeable memory device includes a substrate having a lower electrode disposed thereon. A phase changeable pattern is disposed on the lower electrode and an upper electrode is disposed on the phase changeable pattern that has a tip that extends therefrom and is directed toward the lower electrode.

Abstract: A semiconductor device comprises a semiconductor substrate having an isolation region that defines an active region. The active region has a planar surface and a non-planar surface that extends from the planar surface. The device further includes a gate dielectric layer covering the non-planar surface and a first gate electrode extending across the non-planar surface with the gate dielectric layer therebetween. In addition, a source and drain region are formed on opposite sides of the gate electrode. According to an aspect of the present invention, the resulting device has a non-planar channel region extending between the source region and the drain region. The non-planar channel region is formed along the non-planar surface described above. Further, programmable resistance element is electrically coupled to the drain region to form a phase-change memory device.

Abstract: A phase-change memory device has an oxidation barrier layer to protect against memory cell contamination or oxidation and a method of manufacturing the same. In one embodiment, a semiconductor memory device comprises a molding layer overlying a semiconductor substrate. The molding layer has a protrusion portion vertically extending from a top surface thereof. The device further includes a phase-changeable material pattern adjacent the protrusion portion and a lower electrode electrically connected to the phase-changeable material pattern.

Abstract: In one embodiment, a phase-change memory device has an oxidation barrier layer to protect against memory cell contamination or oxidation and a method of manufacturing the same. In one embodiment, a semiconductor memory device comprises a molding layer overlying a semiconductor substrate. The molding layer has a protrusion portion vertically extending from a top surface thereof. The device further includes a phase-changeable material pattern adjacent the protrusion portion and a lower electrode electrically connected to the phase-changeable material pattern.

Abstract: A phase changeable random access memory (PRAM) and methods for manufacturing the same. An example unit cell of a non-volatile memory, such as a PRAM, includes a MOS transistor, connected to an address line and a data line, where the MOS transistor receives a voltage from the data line. The unit cell further includes a phase change material for changing phase depending on heat generated by the voltage and a top electrode, connected to a substantially ground voltage.

Abstract: In a method of forming a phase-change memory device, a variable resistance member may be formed on a s semiconductor substrate having a contact region, and a first electrode may be formed to contact a first portion of the variable resistance member and to be electrically connected to the contact region. A second electrode may be formed so as to contact a second portion of the variable resistance member.

Abstract: A phase-change memory device may include first and second spaced apart conductive electrodes, and a phase-change memory element coupled between the first and second conductive electrodes. More particularly, a first portion of the phase-change memory element may have a first cross-sectional area along a current path between the first and second conductive electrodes, and a second portion of the phase-change memory element may have a second cross-sectional area along the current path between the first and second conductive electrodes. Moreover, the first and second cross-sectional areas may be different.

Abstract: A phase-change memory device includes a phase-change memory cell having a volume of material which is programmable between amorphous and crystalline states. A write current source selectively applies a first write current pulse to program the phase-change memory cell into the amorphous state and a second write current pulse to program the phase-change memory cell into the crystalline state. The phase-change memory device further includes a restore circuit which selectively applies the first current pulse to the phase-change memory cell to restore at least an amorphous state of the phase-change memory cell.

Abstract: A phase-changeable memory device comprises a substrate and an access transistor formed in and/or on the substrate. Laterally spaced apart first and second conductive patterns are disposed on the substrate and have opposing sidewalls. A conductor electrically connects the first conductive region to a source/drain region of the access transistor. A phase-changeable material region is disposed between the first and second conductive patterns and contacts the opposing sidewalls of the first and second conductive patterns. Contact areas between the conductive patterns and the phase-changeable material region are preferably substantially smaller than contact areas at which the conductive patterns contact conductors (e.g., vias) connected thereto, such that high current densities may be developed in the phase-changeable material. Methods of fabricating such devices are also discussed.

Abstract: A phase change memory device includes a lower electrode and a porous dielectric layer having fine pores on the lower electrode. A phase change layer is provided in the fine pores of the porous dielectric layer. An upper electrode is provided on the phase change layer. Related manufacturing methods are also described.

Abstract: The present invention relates to a composite sheet used for artificial leather with low elongation and excellent softness. The composite sheet for artificial leather comprises: a non-woven fabric layer (1) made of ultra fine fibers having a fineness less than 0.3 denier; a woven or knitted fabric layer (2) constructed from a yarn made of ultra fine fibers having a fineness less than 0.3 denier; and polyurethane resin, wherein the ultra fine fibers of the non-woven fabric layer (1) and the ultra fine fibers of the woven or knitted fabric layer (2) are entangled with each other. The composite sheet of the present invention has a stitching strength of more than 30 kg/mm. an elongation at constant load of less than 20% and a stiffness of less than 80 mm. Since the composite sheet for artificial leather of the present invention is excellent in both form-stability and softness, it is useful for the production of artificial leather for furniture, cars, men's clothing and sundry goods.

Abstract: A phase-changeable memory device comprises a substrate and an access transistor formed in and/or on the substrate. Laterally spaced apart first and second conductive patterns are disposed on the substrate and have opposing sidewalls. A conductor electrically connects the first conductive region to a source/drain region of the access transistor. A phase-changeable material region is disposed between the first and second conductive patterns and contacts the opposing sidewalls of the first and second conductive patterns. Contact areas between the conductive patterns and the phase-changeable material region are preferably substantially smaller than contact areas at which the conductive patterns contact conductors (e.g., vias) connected thereto, such that high current densities may be developed in the phase-changeable material. Methods of fabricating such devices are also discussed.

Abstract: Phase-change memory devices include a phase-change material layer and a first electrode having a contact area therebetween. The contact area extends into a recess of the first electrode to provide current density concentration.

Abstract: A phase changeable memory device includes a substrate having a lower electrode disposed thereon. A phase changeable pattern is disposed on the lower electrode and an upper electrode is disposed on the phase changeable pattern that has a tip that extends therefrom and is directed toward the lower electrode.

Abstract: A phase changeable memory cell that includes a substrate, a bottom electrode, a phase changeable material layer pattern, and a top electrode. The bottom electrode is on the substrate. The phase changeable material layer pattern is on the bottom electrode. The top electrode is on the phase changeable material layer pattern, and has a tip that extends toward the bottom electrode.

Abstract: A phase-changeable memory device comprises a substrate and an access transistor formed in and/or on the substrate. Laterally spaced apart first and second conductive patterns are disposed on the substrate and have opposing sidewalls. A conductor electrically connects the first conductive region to a source/drain region of the access transistor. A phase-changeable material region is disposed between the first and second conductive patterns and contacts the opposing sidewalls of the first and second conductive patterns. Contact areas between the conductive patterns and the phase-changeable material region are preferably substantially smaller than contact areas at which the conductive patterns contact conductors (e.g., vias) connected thereto, such that high current densities may be developed in the phase-changeable material. Methods of fabricating such devices are also discussed.