Abstract: A nonvolatile memory device includes a semiconductor well region of first conductivity type on a semiconductor substrate and a common source diffusion region of second conductivity type extending in the semiconductor well region and forming a P-N rectifying junction therewith. A byte-erasable EEPROM memory array is provided in the semiconductor well region. This byte-erasable EEPROM memory array is configured to support independent erasure of first and second pluralities of EEPROM memory cells therein that are electrically connected to the common source diffusion region.

Abstract: A split-gate non-volatile memory device includes a raised oxide layer on a field oxide region between adjacent split-gate memory cells, the raised oxide layer extending onto first and second floating gates included in the adjacent split-gate memory cells covered by a wordline electrically coupled to respective control gates included in the adjacent split-gate memory cells.

Abstract: A non-volatile memory device comprises a semiconductor substrate having source/drain regions formed at both ends of a channel region, a gate structure forming an offset region by being separated a predetermined distance from the source region and comprising a charge accumulation region and a control gate sequentially deposited in the channel region to at least partially overlap the drain region, and a spacer arranged at each of both side walls of the gate structure. A threshold voltage value of the offset region changes depending on a dielectric constant of the spacer.

Abstract: Example embodiments are directed to a mask ROM, a mask ROM embedded EEPROM and a method of fabricating the same. The mask ROM may include a select gate pattern and a memory gate pattern disposed between a source region and a drain region at each of the on-cell and the off-cell. The on-cell may include a cell diffusion region between the select gate pattern and the memory gate pattern.

Abstract: A non-volatile memory device includes a first sensing line, a first word line, a depletion channel region, and impurity regions. The first sensing line and the first word line are formed adjacent to each other in parallel on a substrate. The first sensing line and the first word line have a tunnel oxide layer, a first conductive pattern, a dielectric layer pattern and a second conductive pattern sequentially stacked on the substrate. The depletion channel region is formed at an upper portion of the substrate under the first sensing line. The impurity regions are formed at upper portions of the substrate exposed by the first sensing line and the first word line.

Abstract: A non-volatile integrated circuit memory device may include a semiconductor substrate having first and second electrically isolated wells of a same conductivity type. A first plurality of non-volatile memory cell transistors may be provided on the first well, and a second plurality of non-volatile memory cell transistors may be provided on the second well. A local control gate line may be electrically coupled with the first and second pluralities of non-volatile memory cell transistors, and a group selection transistor may be electrically coupled between the local control gate line and a global control gate line. More particularly, the group selection transistor may be configured to electrically couple and decouple the local control gate line and the global control gate line responsive to a group selection gate signal applied to a gate of the group selection transistor. Related methods and systems are also discussed.

Abstract: A method of forming a split-gate non-volatile memory cell can include forming first and second adjacent floating gates self-aligned to a field oxide region therebetween. An oxide layer is formed covering the first and second adjacent floating gates and the field oxide region, the oxide layer electrically isolates the first and second adjacent floating gates from one another. A control gate is formed on the oxide layer on the first and second adjacent floating gates. Related devices are also disclosed.

Abstract: A semiconductor memory device having a self-aligned charge trapping layer and a method of manufacturing the same in which a consistent length of an ONO layer is ensured. Here, an insulating stacked structure is self-aligned to a bottom surface of conductive spacers.

Abstract: A semiconductor device having a multi-bit nonvolatile memory cell is provided. The semiconductor device comprises a multi-bit nonvolatile memory unit cell sharing a source and a drain region and having a plurality of transistors. The plurality of transistors each comprise at least one control gate and at least one charge storage region. The charge storage regions are for accumulating charges within each of the plurality of transistors of the memory unit cell. Each of the control gates are connected to at least one control voltage to shift a threshold voltage in each of the plurality of transistors for storing multi-bit per unit cell.

Abstract: In one embodiment, a semiconductor device includes a semiconductor substrate having a first junction region and a second junction region. An insulated floating gate is disposed on the substrate. The floating gate at least partially overlaps the first junction region. An insulated program gate is disposed on the floating gate. The program gate has a curved upper surface. The semiconductor device further includes an insulated erase gate disposed on the substrate and adjacent the floating gate. The erase gate partially overlaps the second junction region.

Abstract: Non-volatile memory devices and methods for fabricating non-volatile memory devices are disclosed. More specifically, split gate memory devices are provided having frameworks that provide increased floating gate coupling ratios, thereby enabling enhanced programming and erasing efficiency and performance.

Abstract: A mask read-only memory (ROM) cell, a method for fabricating the mask ROM cell, a NOR-type mask ROM device, and a method for fabricating the NOR-type mask ROM device are disclosed. A mask ROM cell includes a substrate including an ON cell region and an OFF cell region, a first gate electrode disposed in the ON cell region, and a second gate electrode disposed in the OFF cell region. The mask ROM cell also includes a first impurity region disposed in the substrate proximate a sidewall of the first gate electrode, wherein a portion of the first impurity region is disposed under the first gate electrode; and a second impurity region disposed the substrate proximate a sidewall of the second gate electrode, wherein no portion of the second impurity region is disposed under the second gate electrode.

Abstract: An electrically erasable programmable read-only memory (EEPROM) device includes an EEPROM cell located on a semiconductor substrate, the EEPROM cell including a memory transistor and a selection transistor. A source region and a drain region are located on the semiconductor substrate adjacent to opposite sides of the EEPROM cell, respectively, and a floating region is positioned between the memory transistor and the selection transistor. The source region includes a first doped region, a second doped region and a third doped region, where the first doped region surrounds a bottom surface and sidewalls of the second doped region, and the second doped surrounds a bottom surface and sidewalls of the third doped region. Also, a second impurity concentration of the second doped region is higher than that of the first doped region and lower than that of the third doped region.

Abstract: A non-volatile memory device includes a memory cell block, a first switching block, and a second switching block. A plurality of memory cells are arranged in the memory cell block and each of the memory cells includes a memory transistor having a floating gate and a control gate and is connected to a local bit line and includes a selection transistor connected to the memory transistor in series that is connected to a source line. The first switching block selectively connects a global bit line to the local bit line and the second switching block controls the memory cells in the memory cell block in units of a predetermined number of bits. The first switching block includes at least two switching devices connected in parallel between the global bit line and the local bit line.

Abstract: A non-volatile memory device and a method for fabricating the non-volatile memory device. The non-volatile memory device includes a memory cell located in a first conductive region and has a memory transistor, a selection transistor and a high voltage switching device located in a second conductive region close to the first conductive region. The memory cell is controlled by the high voltage switching device. At least one of the high voltage switching device, the memory transistor, or the selection transistor has a recessed channel region.

Abstract: A mask read-only memory (ROM) includes a dielectric layer formed on a substrate and a plurality of first conductive lines formed on the dielectric layer. A plurality of diodes are formed in the first conductive lines, and a plurality of final vias are formed for a first set of the diodes each representing a first type of memory cell, with no final via being formed for a second set of diodes each representing a second type of memory cell. Each of a plurality of second conductive lines is formed over a column of the diodes.

Abstract: Non-volatile memory devices and methods for fabricating non-volatile memory devices are disclosed. More specifically, split gate memory devices are provided having frameworks that provide increased floating gate coupling ratios, thereby enabling enhanced programming and erasing efficiency and performance.

Abstract: A semiconductor flash memory device. The flash memory device includes a floating gate electrode disposed in a recess having slanted sides in a semiconductor substrate. A gate insulation film is interposed between the floating gate electrode and the semiconductor substrate. A control gate electrode is disposed over the floating gate electrode. The floating gate electrode includes projections adjacent to the slanted sides of the recess.

Abstract: A non-volatile memory integrated circuit device and a method fabricating the same are disclosed. The non-volatile memory integrated circuit device includes a semiconductor substrate, word and select lines, and a floating junction region, a bit line junction region and a common source region. The semiconductor substrate has a plurality of substantially rectangular field regions, and the short and long sides of each substantially rectangular field region are parallel to the row and column directions of a matrix, respectively.

Abstract: In one embodiment, a semiconductor device includes a semiconductor substrate having a first junction region and a second junction region. An insulated floating gate is disposed on the substrate. The floating gate at least partially overlaps the first junction region. An insulated program gate is disposed on the floating gate. The program gate has a curved upper surface. The semiconductor device further includes an insulated erase gate disposed on the substrate and adjacent the floating gate. The erase gate partially overlaps the second junction region.