Abstract: A magnetic memory device includes a first magnetic layer having opposing sidewalls, a tunnel barrier layer on the first magnetic layer, the tunnel barrier layer having a top surface and having opposing sidewalls aligned with the opposing sidewalls of the first magnetic layer, and a second magnetic layer on the tunnel barrier layer, the second magnetic layer having a bottom surface that is narrower than the top surface of the tunnel barrier layer and opposing sidewalls that are spaced apart from the opposing sidewalls of the tunnel barrier layer. A conductive capping layer having opposing sidewalls aligned with the opposing sidewalls of the second magnetic layer is on the second magnetic layer.

Abstract: The present invention relates to a method of forming a phase changeable structure wherein an upper electrode is formed on a phase changeable layer. A material including fluorine can be provided to the phase changeable layer and the upper electrode. The phase changeable layer can be etched to form a phase changeable pattern. Oxygen plasma or water vapor plasma can then be provided to the upper electrode and the phase changeable pattern.

Abstract: Provided are magnetic tunnel junction structures having bended tips at both ends thereof, magnetic RAM cells employing the same and photo masks used in formation thereof. The magnetic tunnel junction structures have a pinned layer pattern, a tunneling insulation layer pattern and a free layer pattern, which are stacked on an integrated circuit substrate. At least the free layer pattern has a main body as well as first and second bended tips each protruded from both ends of the main body when viewed from a plan view.

Abstract: The present invention relates to a phase changeable structure having decreased amounts of defects and a method of forming the phase changeable structure. A stacked composite is first formed by (i) forming a phase changeable layer including a chalcogenide is formed on a lower electrode, (ii) forming an etch stop layer having a first etch rate with respect to a first etching material including chlorine on the phase changeable layer, and (iii) forming a conductive layer having a second etch rate with respect to the first etching material on the etch stop layer. The conductive layer of the stacked composite is then etched using the first etching material to form an upper electrode. The etch stop layer and the phase changeable layer are then etched using a second etching material that is substantially flee of chlorine to form an etch stop pattern and a phase changeable pattern, respectively.

Abstract: A phase change memory device may include an integrated circuit substrate and first and second phase change memory elements on the integrated circuit substrate. The first phase change memory element may include a first phase change material having a first crystallization temperature. The second phase change memory element may include a second phase change material having a second crystallization temperature. Moreover, the first and second crystallization temperatures may be different so that the first and second phase change memory elements are programmable at different temperatures. Related methods and systems are also discussed.

Abstract: Methods of forming a magnetic memory device include oxidizing a top magnetic layer using a conductive capping pattern as a mask. An etch selectivity between an oxidized portion of the top magnetic layer and a tunnel barrier layer may be relatively high. Using the tunnel barrier layer as an etch-stop layer, the oxidized portion of the top magnetic layer is selectively removed to form a top magnetic pattern, and to expose at least a portion of opposite sidewalls of the top magnetic pattern and the tunnel barrier layer. The unoxidized portion of the top magnetic layer forms a top magnetic pattern.

Abstract: In a program method for a multi-level phase change memory device, multi-level data to be programmed in a selected memory cell is received, and a program signal is applied to the selected memory cell according to the received multi-level data. Herein, a rising time of the program signal is set to be longer than a falling time of the program signal.

Abstract: Provided is a resistance variable memory device and a method for operating same. The resistance variable memory device has a phase change material between a top electrode and a bottom electrode. In the method for operating a resistance variable memory, the write current is applied in a direction from the top electrode to the bottom electrode, and the read current is applied in a direction from the bottom electrode to the top electrode. The phase change material is programmed by applying the write current, and a resistance drift of the phase change material is restrained by applying the read current.

Abstract: Provided is a method of programming a resistance variable memory device. The resistance variable memory device includes a memory cell having multi states and a write driver outputting a program pulse for programming the memory cell into one of the multi states. The method of programming the resistance variable memory device includes applying a first program pulse to the resistance variable memory device and applying a second program pulse to a memory cell when the memory cell is programmed into an intermediate state. When the first program pulse is a reset pulse, the reset pulse is an over program pulse, that is, an over reset pulse. Therefore, the resistance variable memory device can secure a sufficient read margin as well as improve a resistance drift margin.

Abstract: A phase-changeable memory device includes a phase-changeable material pattern and first and second electrodes electrically connected to the phase-changeable material pattern. The first and second electrodes are configured to provide an electrical signal to the phase-changeable material pattern. The phase-changeable material pattern includes a first phase-changeable material layer and a second phase-changeable material layer. The first and second phase-changeable material patterns have different chemical, physical, and/or electrical characteristics. For example, the second phase-changeable material layer may have a greater resistivity than the first phase-changeable material layer. For instance, the first phase-changeable material layer may include nitrogen at a first concentration, and the second phase-changeable material layer may include nitrogen at a second concentration that is greater than the first concentration. Related devices and fabrication methods are also discussed.

Abstract: A phase change memory device and method of manufacturing the same is provided. A first electrode having a first surface is provided on a substrate. A second electrode having a second surface at a different level from the first surface is on the substrate. The second electrode may be spaced apart from the first electrode. A third electrode may be formed corresponding to the first electrode. A fourth electrode may be formed corresponding to the second electrode. A first phase change pattern may be interposed between the first surface and the third electrode. A second phase change pattern may be interposed between the second surface and the fourth electrode.

Abstract: A phase-changeable memory device includes a phase-changeable material pattern and first and second electrodes electrically connected to the phase-changeable material pattern. The first and second electrodes are configured to provide an electrical signal to the phase-changeable material pattern. The phase-changeable material pattern includes a first phase-changeable material layer and a second phase-changeable material layer. The first and second phase-changeable material patterns have different chemical, physical, and/or electrical characteristics. For example, the second phase-changeable material layer may have a greater resistivity than the first phase-changeable material layer. For instance, the first phase-changeable material layer may include nitrogen at a first concentration, and the second phase-changeable material layer may include nitrogen at a second concentration that is greater than the first concentration. Related devices and fabrication methods are also discussed.

Abstract: Example embodiments of the present invention disclose a semiconductor memory device and a method of forming a memory device. A semiconductor memory device may include a digit line disposed on a substrate, an intermediate insulating layer covering the digit line, a magnetic tunnel junction (MTJ) pattern disposed on the intermediate insulating layer and over the digit line, the MTJ pattern including a sequentially stacked lower magnetic pattern, upper magnetic pattern, and capping pattern, wherein the capping pattern does not react with the upper magnetic pattern at a temperature above about 280° C., and a bit line connected to the capping pattern and disposed to intersect the digit line.

Abstract: Provided is a phase-change memory device including a phase-change material pattern of which strips are shared by neighboring cells. The phase-change memory device includes a plurality of bottom electrodes arranged in a matrix array. The phase-change material pattern is formed on the bottom electrodes, and the strips of the phase-change material pattern are electrically connected to the bottom electrodes. Each strip of the phase-change material pattern is connected to at least two diagonally neighboring bottom electrodes of the bottom electrodes.

Abstract: A magnetic tunnel junction device includes a magnetically programmable free magnetic layer. The free magnetic layer includes a lamination of at least two ferromagnetic layers and at least one intermediate layer interposed between the at least two ferromagnetic layers.

Abstract: Example embodiments of the present invention disclose a semiconductor memory device and a method of forming a memory device. A semiconductor memory device may include a digit line disposed on a substrate, an intermediate insulating layer covering the digit line, a magnetic tunnel junction (MTJ) pattern disposed on the intermediate insulating layer and over the digit line, the MTJ pattern including a sequentially stacked lower magnetic pattern, upper magnetic pattern, and capping pattern, wherein the capping pattern does not react with the upper magnetic pattern at a temperature above about 280° C., and a bit line connected to the capping pattern and disposed to intersect the digit line.

Abstract: Provided are a phase change memory device and a method of forming the same. According to the phase change memory, a first plug electrode and a second plug electrode are spaced apart from each other in a mold insulating layer. A phase change pattern is disposed on the mold insulating layer. The phase change pattern contacts a top of the first plug electrode and a first potion of a top of the second plug electrode. An interconnection is electrically connected to a second portion of the top of the second plug electrode.

Abstract: Magnetic Random Access Memory (MRAM) devices include a lower electrode and a magnetic tunnel junction on the lower electrode. The magnetic tunnel junction includes a seed layer and a tunneling barrier that is oriented in a same direction as the most closely packed plane direction of the seed layer. An oxide layer may be provided between the lower electrode and the magnetic tunnel junction. The lower electrode may be a titanium-rich TiN layer having more than 50 atomic percent titanium content. Analogous fabrication methods are also described.

Abstract: Magnetic Random Access Memory (MRAM) devices include a lower electrode and a magnetic tunnel junction on the lower electrode. The magnetic tunnel junction includes a seed layer and a tunneling barrier that is oriented in a same direction as the most closely packed plane direction of the seed layer. An oxide layer may be provided between the lower electrode and the magnetic tunnel junction. The lower electrode may be a titanium-rich TiN layer having more than 50 atomic percent titanium content. Analogous fabrication methods are also described.

Abstract: A phase change memory device may include an integrated circuit substrate and first and second phase change memory elements on the integrated circuit substrate. The first phase change memory element may include a first phase change material having a first crystallization temperature. The second phase change memory element may include a second phase change material having a second crystallization temperature. Moreover, the first and second crystallization temperatures may be different so that the first and second phase change memory elements are programmable at different temperatures. Related methods and systems are also discussed.