Abstract: An artificial neuron semiconductor device having a three-dimensional structure includes a first electrode to which a clock signal is applied, a second electrode in which an output signal is generated, an insulation column, a plurality of electrode layers for receiving an electrical signal from at least one synapse circuit, and a phase change layer which is divided into at least two parts by the insulation column and is in contact with at least two side surfaces of the insulation column, and the phase change layer is phase-changed by the plurality of electrode layers.

Abstract: An artificial neuron semiconductor device having a three-dimensional structure includes a first electrode to which a clock signal is applied, a second electrode in which an output signal is generated, an insulation column, a plurality of electrode layers for receiving an electrical signal from at least one synapse circuit, and a phase change layer which is divided into at least two parts by the insulation column and is in contact with at least two side surfaces of the insulation column, and the phase change layer is phase-changed by the plurality of electrode layers.

Abstract: A multi-bit phase change memory device including a phase change material having a plurality of crystalline phases. A non-volatile multi-bit phase change memory device may include a phase change material in a storage node, wherein the phase change material includes a binary or ternary compound sequentially having at least three crystalline phases having different resistance values according to an increase of temperature of the phase change material.

Abstract: In a method of forming a phase-change memory unit, a conductive layer is formed on a substrate having a trench. The conductive layer is planarized until the substrate is exposed to form a first electrode. A spacer partially covering the first electrode is formed. A phase-change material layer is formed on the first electrode and the second spacer. A second electrode is formed on the phase-change material layer. Reset/set currents of the phase-change memory unit may be reduced and deterioration of the phase-change material layer may be reduced and/or prevented.

Abstract: A memory device includes a memory cell array including a NAND flash cell portion including a plurality of first columns of serially-connected flash memory cells and a non-volatile random access memory (NVRAM) cell portion including a plurality of second columns of NVRAM cells. The flash memory cells and the NVRAM cells are arranged such that respective word lines are connected to flash memory cells and NVRAM cells in each of respective rows, which may correspond to page units including flash memory cells and NVRAM cells.

Abstract: A number of read cycles applied to a selected memory location of a memory device, such as a variable-resistance memory device, is monitored. Write data to be written to the selected memory location is received. Selective pre-write verifying and writing of the received write data to the selected memory location occurs based on the monitored number of read cycles. Selectively pre-write verifying and writing of the received write data may include, for example, writing received write data to the selected memory cell region without pre-write verification responsive to the monitored number of read cycles being greater than a predetermined number of read cycles.

Abstract: A multi-bit phase change memory device including a phase change material having a plurality of crystalline phases. A non-volatile multi-bit phase change memory device may include a phase change material in a storage node, wherein the phase change material includes a binary or ternary compound sequentially having at least three crystalline phases having different resistance values according to an increase of temperature of the phase change material.

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: Non-volatile memory devices include an array of phase-changeable memory cells, which have first phase-changeable material patterns therein, and at least one phase-changeable fuse element. This phase-changeable fuse element includes a second phase-changeable material pattern therein with a higher crystallization temperature relative to the first phase-changeable material patterns in the array of phase-changeable memory cells. This higher crystallization temperature may be greater than about 300° C. According to additional embodiments of the present invention, the at least one phase-changeable fuse element includes a composite of the second phase-changeable material pattern and a third phase-changeable material pattern, which is formed of the same material at the first phase-changeable material patterns.

Abstract: A number of read cycles applied to a selected memory location of a memory device, such as a variable-resistance memory device, is monitored. Write data to be written to the selected memory location is received. Selective pre-write verifying and writing of the received write data to the selected memory location occurs based on the monitored number of read cycles.

Abstract: In a method of forming a phase-change memory unit, a conductive layer is formed on a substrate having a trench. The conductive layer is planarized until the substrate is exposed to form a first electrode. A spacer partially covering the first electrode is formed. A phase-change material layer is formed on the first electrode and the second spacer. A second electrode is formed on the phase-change material layer. Reset/set currents of the phase-change memory unit may be reduced and deterioration of the phase-change material layer may be reduced and/or prevented.

Abstract: 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.

Abstract: Magnetic RAM cells have split sub-digit lines surrounded by cladding layers and methods of fabricating the same are provided. The magnetic RAM cells include first and second sub-digit lines formed over a semiconductor substrate. Only a bottom surface and an outer sidewall of the first sub-digit line are covered with a first cladding layer pattern. In addition, only a bottom surface and an outer sidewall of the second sub-digit line are covered with a second cladding layer pattern. The outer sidewall of the first sub-digit line is located distal from the second sub-digit line and the outer sidewall of the second sub-digit line is located distal the first sub-digit line. Methods of fabricating the magnetic RAM cells are also provided.

Abstract: A memory device includes a memory cell array including a NAND flash cell portion including a plurality of first columns of serially-connected flash memory cells and a non-volatile random access memory (NVRAM) cell portion including a plurality of second columns of NVRAM cells. The flash memory cells and the NVRAM cells are arranged such that respective word lines are connected to flash memory cells and NVRAM cells in each of respective rows, which may correspond to page units including flash memory cells and NVRAM cells.

Abstract: A semiconductor device and manufacturing method thereof include a semiconductor substrate, an interlevel dielectric (ILD) layer formed on the semiconductor substrate, a first contact stud formed in the ILD layer, having a width of an entrance portion adjacent to the surface of the ILD layer larger than the width of a contacting portion adjacent to the semiconductor substrate, and a second contact stud spaced apart from the first contact stud and formed in the ILD layer. The semiconductor device further includes a landing pad formed on the ILD layer to contact the surface of the second contact stud, having a width larger than that of the second contact stud. The second contact stud has a width of a contacting portion that is the same as that of an entrance portion. Also, at least one spacer comprising an etch stopper material is formed on the sidewalls of the landing pad and the etch stopper is formed on the landing pad.

Abstract: A conductive portion connects a lower conductive layer formed on a semiconductor substrate provided in a first interlayer insulating layer to an upper conductive layer formed on the lower conductive layer, and provided in a second interlayer insulating layer. This portion is divided into at least one plug and a pad. At least one plug is formed in a first interlayer insulating layer and the lower part of a second interlayer insulating layer. The second interlayer insulating layer is divided into a plurality of interlayer insulating layers so that upper and lower widths of the divided plugs formed in the divided portion of the second interlayer insulating layer are not greatly different from each other. The pad formed on the upper portion of the second interlayer insulating layer has an upper width such that the upper conductive layer connected to the pad is not undesirably connected to an adjacent upper conductive layer via the pad.

Abstract: Magnetic RAM cells have split sub-digit lines surrounded by cladding layers and methods of fabricating the same are provided. The magnetic RAM cells include first and second sub-digit lines formed over a semiconductor substrate. Only a bottom surface and an outer sidewall of the first sub-digit line are covered with a first cladding layer pattern. In addition, only a bottom surface and an outer sidewall of the second sub-digit line are covered with a second cladding layer pattern. The outer sidewall of the first sub-digit line is located distal from the second sub-digit line and the outer sidewall of the second sub-digit line is located distal the first sub-digit line. Methods of fabricating the magnetic RAM cells are also provided.

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: An integrated circuit device is manufactured by forming an insulating layer on a substrate. A capping layer is formed on the insulating layer and both the capping layer and the insulating layer are patterned. Insulating spacers are formed on sidewalls of the insulating layer so that the insulating spacers, the capping layer, and the substrate enclose the insulating layer.

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.