Abstract: Methods of manufacturing three-dimensional semiconductor devices that may include forming a first spacer on a sidewall inside a first opening formed in a first stack structure, forming a sacrificial filling pattern on the spacer to fill the first opening, forming a second stack structure including a second opening exposing the sacrificial filling pattern on the first stack structure, forming a second spacer on a sidewall inside the second opening, removing the sacrificial filling pattern and removing the first spacer and the second spacer.

Abstract: A non-volatile memory device can include a plurality of immediately adjacent offset vertical NAND channels that are electrically coupled to a single upper select gate line or to a single lower select gate line of the non-volatile memory device.

Abstract: Methods of manufacturing vertical semiconductor devices may include forming a mold structure including sacrificial layers and insulating interlayers with a first opening formed therethrough. The sacrificial layers and the insulating interlayers may be stacked repeatedly and alternately on a substrate. The first opening may expose the substrate. Blocking layers may be formed by oxidizing portions of the sacrificial layers exposed by the first opening. A first semiconductor layer pattern, a charge trapping layer pattern and a tunnel insulation layer pattern, respectively, may be formed on the sidewall of the first opening. A second semiconductor layer may be formed on the first polysilicon layer pattern and the bottom of the first opening. The sacrificial layers and the insulating interlayers may be partially removed to form a second opening. The sacrificial layers may be removed to form grooves between the insulating interlayers. Control gate electrodes may be formed in the grooves.

Abstract: A semiconductor device, comprising: a plurality of memory cell strings; a bitline; and an interconnection coupling at least two of the memory cell strings to the bitline. Memory cell strings can be coupled to corresponding bitlines through corresponding interconnections. Alternate memory cell strings can be coupled to different bitlines through corresponding different interconnections.

Abstract: Provided are three-dimensional semiconductor devices. A device includes an electrode structure including conductive patterns sequentially stacked on a substrate, a semiconductor pattern penetrating the electrode structure and including channel regions adjacent to the conductive patterns and vertical adjacent regions between the channel regions, and a semiconductor connecting layer extending from an outer sidewall of the semiconductor pattern to connect the semiconductor pattern to the substrate.

Abstract: The memory devices include a tunneling insulating layer disposed on a substrate, a charge storage layer disposed on the tunneling insulating layer, a blocking insulating layer disposed on the charge storage layer and a control gate electrode disposed on the blocking insulating layer. The control gate electrode may have an edge portion spaced farther apart from the blocking insulating layer than a central portion of the control gate electrode to concentrate charge density distribution on a central portion of a memory cell.

Abstract: According to example embodiments of inventive concepts, a semiconductor memory devices includes: a plurality of memory blocks that each include a plurality of stack structures, global bit lines connected in common to the plurality of memory blocks, block selection lines configured to control electrical connect between the global bit lines and one of the plurality of memory blocks, and vertical selection lines configured to control electrical connected between the global bit lines and one of the plurality of stack structures. Each of the plurality of stack structures includes a plurality of local bit lines, first vertical word lines and second vertical word lines crossing first sidewalls and second sidewalls respectfully of the plurality of stack structures, first variable resistive elements between the plurality of stack structures and the first vertical word lines, and second variable resistive elements between the plurality of stack structures and the second vertical word lines.

Abstract: A gate structure of a non-volatile memory device and a method of forming the same including a tunnel oxide layer pattern, a charge trap layer pattern, a blocking dielectric layer pattern having the uppermost layer including a material having a first dielectric constant greater than that of a material included in the tunnel oxide layer pattern, and first and second conductive layer patterns. The gate structure includes a first spacer to cover at least the sidewall of the second conductive layer pattern. The gate structure includes a second spacer covering the sidewall of the first spacer and the sidewall of the first conductive layer pattern and including a material having a second dielectric constant equal to or greater than the first dielectric constant. In the non-volatile memory device including the gate structure, erase saturation caused by back tunneling is reduced.

Abstract: A nonvolatile memory device and a method of forming the same, the device including a semiconductor substrate; a plurality of gate patterns stacked on the semiconductor substrate; inter-gate dielectric patterns between the gate patterns; active pillars sequentially penetrating the gate patterns and the inter-gate dielectric patterns to contact the semiconductor substrate; and a gate insulating layer between the active pillars and the gate patterns, wherein corners of the gate patterns adjacent to the active pillars are rounded.

Abstract: Provided is a local self-boosting method of a flash memory device including at least one string having memory cells respectively connected to wordlines. The local self-boosting method includes forming a potential well at a channel of the string and forming potential walls at the potential well to be disposed at both sides of a channel of a selected one of the memory cells. The channel of the selected memory cell is locally limited by the potential walls and boosted when a program voltage is applied to the selected memory cell.

Abstract: Three-dimensional semiconductor memory devices and methods of fabricating the same. The three-dimensional semiconductor devices include an electrode structure with sequentially-stacked electrodes disposed on a substrate, semiconductor patterns penetrating the electrode structure, and memory elements including a first pattern and a second pattern interposed between the semiconductor patterns and the electrode structure, the first pattern vertically extending to cross the electrodes and the second pattern horizontally extending to cross the semiconductor patterns.

Abstract: One example embodiment of a semiconductor device includes a memory cell array formed on a substrate. The memory cell array includes a gate stack including alternating conductive and insulating layers. A first lower conductive layer in the gate stack has a portion disposed below a first upper conductive layer in the gate stack, and a first contact area of the first lower conductive layer is disposed higher than a second contact area of the first upper conductive layer. The semiconductor device further includes first and second contact plugs extending into the gate stack to contact the first and second contact areas, respectively.

Abstract: A nonvolatile memory device and a method of forming the same, the device including a semiconductor substrate; a plurality of gate patterns stacked on the semiconductor substrate; inter-gate dielectric patterns between the gate patterns; active pillars sequentially penetrating the gate patterns and the inter-gate dielectric patterns to contact the semiconductor substrate; and a gate insulating layer between the active pillars and the gate patterns, wherein corners of the gate patterns adjacent to the active pillars are rounded.

Abstract: A gate structure of a non-volatile memory device and a method of forming the same including a tunnel oxide layer pattern, a charge trap layer pattern, a blocking dielectric layer pattern having the uppermost layer including a material having a first dielectric constant greater than that of a material included in the tunnel oxide layer pattern, and first and second conductive layer patterns. The gate structure includes a first spacer to cover at least the sidewall of the second conductive layer pattern. The gate structure includes a second spacer covering the sidewall of the first spacer and the sidewall of the first conductive layer pattern and including a material having a second dielectric constant equal to or greater than the first dielectric constant. In the non-volatile memory device including the gate structure, erase saturation caused by back tunneling is reduced.

Abstract: An error correction apparatus, a method thereof, and a memory device including the apparatus are provided. The error correction apparatus may include: a determination unit configured to determine whether a number of errors in a read word being read and extracted from a multi-level cell (MLC) exists in an error correcting capability range; a read voltage control unit configured to either increase or decrease a read voltage applied to the MLC when the number of errors in the read word is outside the error correcting capability range; and a codeword determination unit configured to analyze a bit error based on the increase or decrease of the read voltage, and to select a codeword corresponding to the analyzed bit error based on a selected read error pattern. Through this, it may be possible to efficiently correct a read error that occurs when the data of the memory device is maintained for a long time.

Abstract: Memory devices and/or methods of storing memory data bits are provided. A memory device includes a multi-level cell (MLC) array including a plurality of MLCs, an error correction unit configured to encode data to be recorded in an MLC, where the encoded data is converted to convert the encoded data into a codeword, an error pattern analysis unit configured to analyze a first data pattern included in the codeword corresponding to an error pattern included in the codeword and a data conversion unit configured to convert the analyzed first data pattern into a second data pattern. According to the above memory devices and/or methods, it is possible to efficiently reduce a data error that occurs when the data is stored for a relatively long period of time, thereby improving reliability.

Abstract: Provided are three-dimensional semiconductor devices. A device includes an electrode structure including conductive patterns sequentially stacked on a substrate, a semiconductor pattern penetrating the electrode structure and including channel regions adjacent to the conductive patterns and vertical adjacent regions between the channel regions, and a semiconductor connecting layer extending from an outer sidewall of the semiconductor pattern to connect the semiconductor pattern to the substrate.

Abstract: Nonvolatile memory devices include a plurality of nonvolatile memory cell transistors having respective channel regions within a semiconductor layer formed of a first semiconductor material and respective source/drain regions formed of a second semiconductor material, which has a smaller bandgap relative to the first semiconductor material. The source/drain regions can form non-rectifying junctions with the channel regions. The source/drain regions may include germanium (e.g., Ge or SiGe regions), the semiconductor layer may be a P-type silicon layer and the source/drain regions of the plurality of nonvolatile memory cell transistors may be P-type germanium or P-type silicon germanium.

Abstract: Three-dimensional (3D) semiconductor memory devices are provided. According to the 3D semiconductor memory device, a gate structure includes gate patterns and insulating patterns alternately stacked on a semiconductor substrate. A vertical active pattern penetrates the gate structure. A gate dielectric layer is disposed between a sidewall of the vertical active pattern and each of the gate patterns. A semiconductor pattern is disposed on the gate structure and is connected to the vertical active pattern. A string drain region is formed in a portion of the semiconductor pattern and is spaced apart from the vertical active pattern.

Abstract: A semiconductor memory device is provided including first and second cell strings formed on a substrate, the first and second cell strings jointly connected to a bit line, wherein each of the first and second cell strings includes a ground selection unit, a memory cell, and first and second string selection units sequentially formed on the substrate to be connected to each other, wherein the ground selection unit is connected to a ground selection line, the memory cell is connected to a word line, the first string selection unit is connected to a first string selection line, and the second string selection unit is connected to a second string selection line, and wherein the second string selection unit of the first cell string has a channel dopant region.