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 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 split gate type nonvolatile semiconductor memory device and a method of fabricating a split gate type nonvolatile semiconductor memory device are provided. A gate insulating layer and a floating-gate conductive layer are formed on a semiconductor substrate. A mask layer pattern is formed on the floating-gate conductive layer to define a first opening extending in a first direction. First sacrificial spacers having a predetermined width are formed on both sidewalls corresponding to the mask layer pattern. An inter-gate insulating layer is formed on the floating-gate conductive layer. The first sacrificial spacers are removed, and the floating-gate conductive layer is etched until the gate insulating layer is exposed. A tunneling insulating layer is formed on an exposed portion of the floating-gate conductive layer. A control-gate conductive layer is formed on a surface of the semiconductor substrate. Second sacrificial spacers having predetermined widths are formed on the control-gate conductive layer.

Abstract: A flash memory device including a tunnel dielectric layer, a floating gate layer, an interlayer dielectric layer and at least two mold layers formed on a semiconductor substrate and a method of manufacturing the same are provided. By sequentially patterning the layers, a first mold layer pattern and a floating gate layer pattern aligned with each other are formed. Exposed portions of side surfaces of the first mold layer pattern are selectively lateral etched, thereby forming a first mold layer second pattern having grooves in its sidewalls. A gate dielectric layer is formed on the semiconductor substrate adjacent to the floating gate layer pattern. A control gate having a width that is determined by the grooves in the second mold layer pattern is formed on the gate dielectric layer. By removing the first mold layer second pattern, spacers are formed on sidewalls of the control gate.

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: Provided are an EEPROM cell, an EEPROM device, and methods of manufacturing the EEPROM cell and the EEPROM device. The EEPROM cell is formed on a substrate including a first region and a second region. A first EEPROM device having a first select transistor and a first memory transistor is disposed in the first region, while a second EEPROM device having a second select transistor and a second memory transistor is disposed in the second region. In the first region, a first drain region and a second floating region are formed apart from each other. In the second region, a second drain region and a second floating region are formed apart from each other. A first impurity region, a second impurity region, and a third impurity region are disposed in a common source region between the first and second regions of the substrate. The first and third impurity regions form a DDD structure, and the first and second impurity region form an LDD structure.

Abstract: In a method for forming a semiconductor device and a semiconductor device formed in accordance with the method, a thin dielectric layer is provided between a lower conductive layer and an upper conductive layer. In one embodiment, the thin dielectric layer comprises an inter-gate dielectric layer, the lower conductive layer comprises a floating gate and the upper dielectric layer comprises a control gate of a transistor, for example, a non-volatile memory cell transistor. The thin dielectric layer is formed using a heat treating process that results in reduction of surface roughness of the underlying floating gate, and results in a thin silicon oxy-nitride layer being formed on the floating gate. In this manner, the thin dielectric layer provides for increased capacitive coupling between the lower floating gate and the upper control gate. This also leads to a lowered programming voltage, erasing voltage and read voltage for the transistor, while maintaining the threshold voltage in a desired range.

Abstract: A tunneling dielectric layer, a charge trapping layer, a first length defining layer, and a second length defining layer are sequentially deposited on a semiconductor substrate. These layers are sequentially patterned. Exposed both sidewalls of the first length defining layer first pattern are recessed by selective side etching. After forming a blocking layer for covering the exposed charge trapping layer and a gate layer for filling the recessed portion, the gate layer is patterned to form spacer shaped gates. Dopant regions for source and drain regions are formed on the semiconductor substrate adjacent the gates.

Abstract: A method of manufacturing a split gate type nonvolatile semiconductor memory device in which control gates are formed by a self aligning process.

Abstract: Silicon-oxide-nitride-oxide-silicon (SONOS) devices and methods of manufacturing the same are provided. According to one aspect, a SONOS device includes a semiconductor substrate having a first surface, a second surface of lower elevation than the first surface, and a third surface perpendicular and between the first and second surfaces; a tunnel dielectric layer on the semiconductor substrate; a charge trapping layer in a form of a spacer on the tunnel dielectric layer on the third surface; a charge isolation layer on the tunnel dielectric layer, which covers the charge trapping layer; a gate that extends over a portion of the first surface, over a portion of the second surface, and is adjacent to a portion of the third surface of the semiconductor substrate on the charge isolation layer; a first impurity region formed below the first surface and near the gate; and a second impurity region formed below the second surface, opposite the first impurity region.

Abstract: In a local-length nitride SONOS device and a method for forming the same, a local-length nitride floating gate structure is provided for mitigating or preventing lateral electron migration in the nitride floating gate. The structure includes a thin gate oxide, which leads to devices having a lower threshold voltage. In addition, the local-length nitride layer is self-aligned, which prevents nitride misalignment, and therefore leads to reduced threshold voltage variation among the devices.

Abstract: Provided are a local SONOS-type memory device and a method of manufacturing the same. The device includes a gate oxide layer formed on a silicon substrate; a conductive spacer and a dummy spacer, which are formed on the gate oxide layer and separated apart from each other, the conductive spacer and the dummy spacer having round surfaces that face outward; a pair of insulating spacers formed on a sidewall of the conductive spacer and a sidewall of the dummy spacer which face each other; an ONO layer formed in a self-aligned manner between the pair of insulating spacers; a conductive layer formed on the ONO layer in a self-aligned manner between the pair of insulating spacers; and source and drain regions formed in the silicon substrate outside the conductive spacer and the dummy spacer.

Abstract: Embodiments of the invention include a gate insulating layer formed on a semiconductor substrate; a spacer-type floating gate and a spacer-type dummy pattern, which are formed on the gate insulating layer and separated apart from each other, the floating gate and the dummy pattern having round surfaces that face outward; a pair of insulating spacers, which are formed on a sidewall of the floating gate and a sidewall of the dummy pattern which face each other; a control gate formed in a self-aligned manner between the pair of insulating spacers; a tunnel insulating layer interposed between the floating gate and the control gate; and source and drain regions formed in the semiconductor substrate outside the floating gate and the dummy pattern.

Abstract: The present invention relates to a high voltage transistor and method of manufacturing the same.

Abstract: A self-aligned 1 bit silicon oxide nitride oxide silicon (SONOS) cell and a method of fabricating the same has high uniformity between adjacent SONOS cells, since the lengths of nitride layers do not vary due to misalignment when etching word lines of the 1 bit SONOS cells. An insulating layer pattern that forms a sidewall of a word line is formed on a semiconductor substrate, and a word line for a gate is formed on the sidewall thereof. Etching an ONO layer using a self-aligned etching spacer provides uniform adjacent SONOS cells.

Abstract: A device is described comprising a substrate of a first conductivity type having a first dopant concentration, a first well formed in the substrate, a second well of the first conductivity type formed in the substrate and being deeper than the first well, the second well having a higher dopant concentration than the first dopant concentration, and a nonvolatile memory cell formed on the second well. A device is described comprising four wells of various conductivity types with a nonvolatile memory cell formed on the second well. A device is described comprising a plurality of wells for isolating transistors of a plurality of voltage ranges, wherein each one of the plurality of wells contains at least one transistor of a particular voltage range, and wherein transistors of only one of the plurality of voltage ranges are within each of the plurality of wells.

Abstract: An EEPROM cell structure, having varied gate-dielectric thickness, can include: a semiconductor substrate; a memory transistor and a select transistor on the substrate; and a floating junction formed in the substrate between the transistors and extending partially underneath the memory transistor; a gate-dielectric layer in the memory transistor, along a lateral direction, being arranged into a tunnel region having thickness Ttunnel and overlying a portion of the floating junction, a near-channel region having thickness Tnear>Ttunnel and located at a side of the tunnel region opposite the select transistor, and a far-channel region having thickness Tfar<Tnear and located at a side of the near-channel-region opposite the tunnel-region. A related method making such an EEPROM cell structure has corresponding steps.