Abstract: NAND flash memory cell array and fabrication process in which cells having memory gates and charge storage layers are densely packed, with the memory gates in adjacent cells either overlapping or self-aligned with each other. The memory cells are arranged in rows between bit line diffusions and a common source diffusion, with the charge storage layers positioned beneath the memory gates in the cells. The memory gates are either polysilicon or polycide, and the charge storage gates are either a nitride or the combination of nitride and oxide. Programming is done either by hot electron injection from silicon substrate to the charge storage gates to build up a negative charge in the charge storage gates or by hot hole injection from the silicon substrate to the charge storage gates to build up a positive charge in the charge storage gates. Erasure is done by channel tunneling from the charge storage gates to the silicon substrate or vice versa, depending on the programming method.

Abstract: A split gate flash memory cell comprising a semiconductor substrate having a first insulating layer thereon and a floating gate with a first width is disclosed. The cell further comprises a second insulating layer, a control gate and a cap on the floating gate in sequence. The cap layer, the control gate and the second insulating layer have a same second width less than the first width. The cell also comprises a third insulating layer over the semiconductor substrate, the sidewalls of the control gate, the second insulating layer, the floating gate, and the first insulating layer. In addition, an erase gate formed on the third insulating layer is provided.

Abstract: A method of fabricating a flash memory device includes depositing and etching an insulating layer on a substrate having STI structures, depositing a first polysilicon layer over the insulating layer and the substrate, etching the first polysilicon layer to form floating gates and removing the insulating layer. The method also includes forming a first photoresist pattern, performing a first ion implantation using the first photoresist pattern to form first source/drain regions in the substrate and adjacent to the floating gate, removing the first photoresist pattern, depositing an ONO layer on the resulting structure, depositing a second polysilicon layer over the ONO layer, and etching the second polysilicon layer to form a control gate and at least one select gate. The method concludes by forming a second photoresist pattern and performing a second ion implantation using the second photoresist pattern to form second source/drain regions in the substrate and adjacent to the select gate.

Abstract: A method of forming a source contact of a NAND flash memory, including the steps of forming a tunnel oxide film on a semiconductor substrate, and then removing the tunnel oxide film in a region in which the source contact will be formed; sequentially forming a first polysilicon layer and a dielectric layer on the entire structure, and then removing the dielectric layer of a region in which select transistors will be formed; sequentially forming a second polysilicon layer on the regions for which the dielectric layer has been removed, forming a conductive film on the second polymer layer, and forming a hard mask on the conductive film; performing an etch process using a gate mask to etch a cell region up to the dielectric layer and at the same time, to etch the region in which the source contact will be formed up to on the tunnel oxide film, thereby forming source lines; performing an ion implantation process on the semiconductor substrate exposed at both sides of the source lines; sequentially etching the die

Abstract: A NAND flash memory device and method of manufacturing the same is disclosed. Source and drain select transistor gates are recessed lower than an active region of a semiconductor substrate. A valid channel length of the source and drain select transistor gates is longer than a channel length of memory cell gates. Accordingly, an electric field between a source region and a drain region of the select transistor can be reduced. It is thus possible to prevent program disturbance from occurring in edge memory cells adjacent to the source and drain select transistors in non-selected cell strings.

Abstract: An EEPROM device includes a device isolation layer disposed at a predetermined region of a semiconductor substrate to define active regions, a pair of control gates crossing the device isolation layers and an active region, a pair of selection gates interposed between the control gates to cross the device isolation layers and the active region and a floating gate and an intergate dielectric pattern stacked sequentially between the control gates and the active region The EEPROM device further includes a gate insulation layer of a memory transistor interposed between the floating gate and the active region and a tunnel insulation layer thinner than the gate insulation layer of the memory transistor and a gate insulation layer of a selection transistor interposed between the selection gates and the active region. The tunnel insulation layer is aligned at one side adjacent to the floating gate.

Abstract: In the method for manufacturing a semiconductor device (100), which comprises a semiconducting body (1) having a surface (2) with a source region (3) and a drain region (4) defining a channel direction (102) and a channel region (101), a first stack (6) of layers on top of the channel region (101), the first stack (6) comprising, in this order, a tunnel dielectric layer (11), a charge storage layer (10) for storing an electric charge and a control gate layer (9), and a second stack (7) of layers on top of the channel region (101) directly adjacent to the first stack (6) in the channel direction (102), the second stack (7) comprising an access gate layer (14) electrically insulated from the semiconducting body (1) and from the first stack (6), initially a first sacrificial layer (90) is used, which is later replaced by the control gate layer (9).

Abstract: The present invention provides a method for manufacturing a semiconductor device including the steps of forming a flash memory cell provided with a floating gate, an intermediate insulating film, and a control gate, forming first and second impurity diffusion regions, thermally oxidizing surfaces of a silicon substrate and the floating gate, etching a tunnel insulating film in a partial region through a window of a resist pattern; forming a metal silicide layer on the first impurity diffusion region in the partial region, forming an interlayer insulating film covering the flash memory cell, and forming, in a first hole of the interlayer insulating film, a conductive plug connected to the metal silicide layer.

Abstract: A semiconductor device comprises a memory cell array portion and peripheral circuit portion, wherein a first insulation film including elements as main components other than nitrogen fills between the memory cell gate electrodes of the memory cell array portion, the first insulation film is formed as a liner on a sidewall of a peripheral gate electrode of the peripheral circuit portion simultaneously with the memory cell portion, and a second insulation film including nitrogen as the main component is formed on the sidewall of the peripheral gate electrode via the first insulation film, thus enabling not only the formation of the memory cell portion having high reliability, but also the formation of a peripheral circuit with good efficiency, simultaneously, and avoiding gate offset of a peripheral gate.

Abstract: According to an aspect of the present invention, there is provided a semiconductor memory device including: a semiconductor substrate having: first device regions divided by first isolation films and second device regions divided by second isolation films a gate insulating film formed on the semiconductor substrate; a first element including: a first gate formed on the gate insulating film in the first device regions, a first inter-electrode insulating film formed on the first gate and on the first isolation films, and a second gate formed on the first inter-electrode insulating film; and a second element including: a third gate formed on the gate insulating film in the second device regions, and a fourth gate formed on the third gate and on the second isolation films; wherein a thickness of the third gate is larger than a thickness of the first gate.

Abstract: The memory cell matrix encompasses (a) a plurality device isolation films running along column direction, (b) first conductive layers arranged along row and column-directions, adjacent groups of the first conductive layers are isolated from each other by the device isolation film disposed between the adjacent groups, (c) lower inter-electrode dielectrics arranged respectively on crests of the corresponding first conductive layers, (d) an upper inter-electrode dielectric arranged on the lower inter-electrode dielectric made of insulating material different from the lower inter-electrode dielectrics, and (e) second conductive layers running along the row-direction, arranged on the upper inter-electrode dielectric.

Abstract: A NAND memory device has a source line connected to two or more columns of serially-connected floating-gate transistors. The source line includes a first conductive layer formed on a substrate and coupled to source select gates associated with the two or more columns of serially-connected floating-gate transistors. The source line also includes a second conductive layer formed on the first conductive layer, where the second layer has a greater electrical conductivity than the first conductive layer.

Abstract: In a method for producing a semiconductor structure a semiconductor a substrate with a top surface is provided. A gate dielectric layer is provided on the top surface and on the gate dielectric layer is provided a memory cell array region with a first plurality of gate stacks and a peripheral element region with a second plurality of gate stacks. A dielectric layer is provided over the memory cell array region and the peripheral element region. A first source/drain implantation over the memory cell array region and the peripheral element region is carried out, a blocking mask over the memory cell array region is formed, the dielectric layer is removed using the blocking mask, and a second source/drain implantation over the memory cell array region and the peripheral element region is carried out, wherein the memory cell array region is protected by a mask.

Abstract: Disclosed is a method for manufacturing a NAND flash device. After a source line plug hole is formed, a drain contact plug hole is formed. The holes are filled with a conductive material film and are then polished. It is therefore possible to simplify the process since a blanket etch process step is omitted. Moreover, loss of a drain contact plug by the blanket etch process is prevented. It is therefore possible to improve the electrical properties of a device and reduce the manufacturing cost price.

Abstract: NAND memory arrays and methods are provided. A plurality of first gate stacks is formed on a first dielectric layer that is formed on a substrate of a NAND memory array. The first dielectric layer and the plurality of first gate stacks formed thereon form a NAND string of memory cells of the memory array. A second gate stack is formed on a second dielectric layer that is formed on the substrate adjacent the first dielectric layer. The second dielectric layer with the second gate stack formed thereon forms a drain select gate adjacent an end of the NAND string. The second dielectric layer is thicker than the first dielectric layer.

Abstract: A one time programmable memory including a substrate, a plurality of isolation structures, a first transistor, and a second transistor is provided. The isolation structures are disposed in the substrate for defining an active area. A recess is formed on each of the isolation structures so that the top surface of the isolation structure is lower than that of the substrate. The first transistor is disposed on the active area of the substrate and is extended to the sidewall of the recess. The gate of the first transistor is a select gate. The second transistor is disposed on the active area of the substrate and is connected to the first transistor in series. The gate of the second transistor is a floating gate which is disposed across the substrate between the isolation structures in blocks and is extended to the sidewall of the recess.

Abstract: A NAND memory device has a source line connected to two or more columns of serially-connected floating-gate transistors. The source line includes a first conductive layer formed on a substrate and coupled to source select gates associated with the two or more columns of serially-connected floating-gate transistors. The source line also includes a second conductive layer formed on the first conductive layer, where the second layer has a greater electrical conductivity than the first conductive layer.

Abstract: The present invention relates to a method of forming a source contact of a flash memory device.

Abstract: A method of manufacturing an EEPROM cell includes growing a first oxide layer on a semiconductor substrate; forming a first conductive layer on the first oxide layer; forming a first conductive pattern and a tunneling oxide layer by patterning the first conductive layer and the first oxide layer, the tunneling oxide layer being disposed under the first conductive pattern; forming a gate oxide layer on sidewalls of the first conductive pattern and the substrate and forming a second conductive pattern on both sides of the first conductive pattern; forming a conductive layer for a floating gate by electrically connecting the first conductive pattern to the second conductive pattern; forming a coupling oxide layer on the conductive layer for the floating gate; forming a third conductive layer on the coupling oxide layer; and forming a select transistor and a control transistor by patterning the third conductive layer, the coupling oxide layer, and the conductive layer for the floating gate.

Abstract: A source line is formed by forming a source slot in a bulk insulation layer overlying a substrate to expose a portion of a substrate within the source slot, where the exposed portion of the substrate includes source regions of select gates associated with two or more columns of serially-connected floating-gate transistors formed on the substrate. A layer of epitaxial silicon is grown on the exposed portion so as to partially fill the source slot. A conductive layer is formed on the bulk insulation layer and on the layer of epitaxial silicon so as to substantially fill an unfilled portion of the source slot. The conductive layer is removed from a surface of the bulk insulation layer.

Abstract: Nonvolatile memory devices and methods for fabricating the same are provided. The device includes first and second base patterns disposed under floating and selection gates, respectively, at an active region. A channel region is formed in the active region between the first and second base patterns, and source and drain regions are formed in the active region adjacent to the first and second base patterns, respectively. The method includes forming first and second base patterns on a semiconductor substrate to be separated from each other by a predetermined space. A channel region is formed in the semiconductor substrate between the first and second base patterns. Source and drain regions are formed in the semiconductor substrate adjacent to the reverse side of the channel region on the basis of the first and second base patterns, respectively. A tunnel oxide layer is formed on a predetermined region of the channel region. A memory gate is formed to cover the first base pattern and the tunnel oxide layer.

Abstract: The invention relates to a bit line structure having a surface bit line (DLx) and a buried bit line (SLx), the buried bit line (SLx) being formed in a trench with a trench insulation layer (6) and being connected to doping regions (10) with which contact is to be made via a covering connecting layer (12) and a self-aligning terminal layer (13) in an upper partial region of the trench.

Abstract: A flash memory cell array comprises a substrate, a string of memory cell structures and source region/drain region. Each of memory cell structures includes a stack gate structure including a select gate dielectric layer, a select gate and a gate cap layer formed on the substrate; a spacer is set on the sidewall of the select gate; a control gate connected to the stack gate structure is set on the one side of the stack gate structure; a floating gate is set between the control gate and the substrate; an inter-gate dielectric layer is set between the control gate and the floating gate; and a tunneling dielectric layer is set between the floating gate and the substrate. The source region/drain region is set in the substrate near outer control gate and stack gate structure of the flash memory cell array.

Abstract: There is provided a method of manufacturing a semiconductor device including a nonvolatile memory including forming an element isolation area surrounding an element area in a semiconductor substrate doped with a first type conductive impurity, forming a gate insulating film on the element area, forming selectively a cap film on the gate insulating film, burying selectively with a mask film surrounding the cap film on the gate insulating film, forming a tunnel window by removing selectively the cap film, forming an impurity diffusion layer in a surface region of the semiconductor substrate underneath the gate insulating film by introducing a second type conductive impurity using the mask film as a mask, removing the gate insulating film in the tunnel window, forming a tunnel insulating film in the tunnel window, forming a floating gate electrode film, an inter-gate electrode film, and a control gate electrode film on the tunnel insulating film, and forming a source-drain in the semiconductor substrate to inter

Abstract: Methods and apparatus are provided. A NAND memory device has a source line connected to two or more columns of serially-connected floating-gate transistors. The source line includes a first conductive layer formed on a substrate and coupled to source select gates associated with the two or more columns of serially-connected floating-gate transistors. The source line also includes a second conductive layer formed on the first conductive layer, where the second layer has a greater electrical conductivity than the first conductive layer.