Patent application number | Description | Published |
20080316804 | Multiple level cell phase-change memory devices having controlled resistance drift parameter, memory systems employing such devices and methods of reading memory devices - In a method of controlling resistance drift in a memory cell of a resistance-changeable material memory device, the resistance changeable material in the memory cell is treated so that a drift parameter for the memory cell is less than about 0.18, wherein a change in resistance of a memory cell over the time period is determined according to the relationship: | 12-25-2008 |
20090017577 | Methods of Forming Phase Change Memory Devices Having Bottom Electrodes - Phase change memory devices can have bottom patterns on a substrate. Line-shaped or L-shaped bottom electrodes can be formed in contact with respective bottom patterns on a substrate and to have top surfaces defined by dimensions in x and y axes directions on the substrate. The dimension along the x-axis of the top surface of the bottom electrodes has less width than a resolution limit of a photolithography process used to fabricate the phase change memory device. Phase change patterns can be formed in contact with the top surface of the bottom electrodes to have a greater width than each of the dimensions in the x and y axes directions of the top surface of the bottom electrodes and top electrodes can be formed on the phase change patterns, wherein the line shape or the L shape represents a sectional line shape or a sectional L shape of the bottom electrodes in the x-axis direction. | 01-15-2009 |
20090026436 | Phase change memory devices and methods of forming the same - A method of forming a phase change memory device includes forming a core pattern on a substrate, conformally forming a heat conductive layer on the substrate including the core pattern, anisotropically etching the heat conductive layer down to a top surface of the core pattern to form a heat electrode surrounding a sidewall of the core pattern, and forming a phase change memory pattern connected to a top surface of the heat electrode. | 01-29-2009 |
20090230376 | RESISTIVE MEMORY DEVICES - Provided is a resistive memory device that can be integrated with a high integration density and method of forming the same. In an embodiment, a bit line is formed of copper using a damascene technique, and when the copper bit line, a copper stud may be formed around the copper bit line | 09-17-2009 |
20090230378 | RESISTIVE MEMORY DEVICES - Provided is a resistive memory device that can be integrated with a high integration density and method of forming the same. An insulating layer enclosing a resistive memory element and an insulating layer enclosing a conductive line connected with the resistive memory element have different stresses, hardness, porosity degrees, dielectric constant or heat conductivities. | 09-17-2009 |
20090242866 | Phase change memory device and method of fabricating the same - A semiconductor device includes an insulating layer on a substrate, a first electrode in the insulating layer having a first upper surface and a second upper surface, a second electrode in the insulating layer spaced apart from the first electrode by a first distance and having a third upper surface and a fourth upper surface, the third upper surface being disposed at a substantially same level as the first upper surface, and the fourth upper surface being disposed at a substantially same level as the second upper surface, a first phase change material pattern covering a part of the first upper surface of the first electrode, and a second phase change material pattern covering a part of the third upper surface of the second electrode, wherein an interface region between the second phase change pattern and the second electrode is spaced apart from an interface region between the first phase change pattern and the first electrode by a second distance greater than the first distance. | 10-01-2009 |
20100144090 | PHASE CHANGE MEMORY DEVICES HAVING DUAL LOWER ELECTRODES AND METHODS OF FABRICATING THE SAME - A semiconductor device includes a semiconductor substrate and a lower interlayer insulating layer disposed on the substrate. An opening passing through the lower interlayer insulating layer and exposing the substrate is included. A buried insulating pattern is disposed in the opening. First and second conductive layer patterns are sequentially stacked to surround the sidewall and bottom of the buried insulating pattern. A phase change material pattern is included, which is disposed on the lower interlayer insulating layer in contact with a top surface of the second conductive layer pattern, and spaced apart from the first conductive layer pattern. An upper interlayer insulating layer covering the lower interlayer insulating layer and the phase change material pattern is included. A conductive plug is included, which passes through the upper interlayer insulating layer and is electrically connected to the phase change material pattern. A method of fabricating the semiconductor device is also provided. | 06-10-2010 |
20100252795 | Phase change memory device - Provided is a phase change memory device and a method of manufacturing the phase change memory device. In the phase change memory device, since a flat surface of a buffer pattern and a lower electrode are stably in contact with each other in a center of a recess, a resistance of a contact surface between the lower electrode and the buffer pattern can be minimized and thereby the phase change memory device can be operated by a small current. Since a method of manufacturing the phase change memory device needs one time etching process to form a recess exposing a semiconductor substrate to an insulating layer until forming a lower electrode after forming a device isolation layer, it is very economical. | 10-07-2010 |
20110044098 | Nonvolatile Memory Cells Having Phase Changeable Patterns Therein for Data Storage - A nonvolatile memory cell includes a substrate and a phase changeable pattern configured to retain a state of the memory cell, on the substrate. An electrically insulating layer is provided, which contains a first electrode therein in contact with the phase changeable pattern. The first electrode has at least one of an L-shape when viewed in cross section and an arcuate shape when viewed from a plan perspective. A lower portion of the first electrode may be ring-shaped when viewed from the plan perspective. The lower portion of the first electrode may also have a U-shaped cross-section. An upper portion of the first electrode may also have an arcuate shape that spans more than 180° of a circular arc. | 02-24-2011 |
20130234100 | NONVOLATILE MEMORY CELLS HAVING PHASE CHANGEABLE PATTERNS THEREIN FOR DATA STORAGE - Phase change memory devices can have bottom patterns on a substrate. Line-shaped or L-shaped bottom electrodes can be formed in contact with respective bottom patterns on a substrate and to have top surfaces defined by dimensions in x and y axes directions on the substrate. The dimension along the x-axis of the top surface of the bottom electrodes has less width than a resolution limit of a photolithography process used to fabricate the phase change memory device. Phase change patterns can be formed in contact with the top surface of the bottom electrodes to have a greater width than each of the dimensions in the x and y axes directions of the top surface of the bottom electrodes and top electrodes can be formed on the phase change patterns, wherein the line shape or the L shape represents a sectional line shape or a sectional L shape of the bottom electrodes in the x-axis direction. | 09-12-2013 |
20140246308 | THREE-COMPARTMENT-CELL ONE-PORT TYPE ELECTROLYSIS APPARATUS - A three-compartment-cell one-port type electrolysis apparatus having a three-compartment-cell one-port structure which solves the problems of a one-compartment-cell type electrolytic bath and a two-compartment-cell type electrolytic bath, can generate high-purity electrolytic water having strong functionality by consuming only minute amounts of electrolyte, can generate various kinds of electrolyzed water using various electrolytes in a salt state, particularly provides oxidized water or reduced water having an optimized pH according to the various uses by selectively combining the oxidized water and the reduced water, and minimizes the consumption of water. | 09-04-2014 |