Abstract: A method of fabricating an integrated circuit memory device including forming a first and second inter-level dielectric layer, an anti-reflective coating layer, and a plurality of electrical connections is disclosed.

Abstract: A semiconductor device having a substrate, a dielectric layer over the substrate, a first gate conductor, an inter-gate dielectric structure and a second gate conductor is disclosed. A gate dielectric structure is disposed between the first gate conductor and the dielectric layer, and may include two or more dielectric films disposed in an alternating manner. The inter-gate dielectric structure may be disposed between the first gate conductor and the second gate conductor, and may include two or more dielectric films disposed in an alternating manner. The second gate conductor is formed in an L shape such that the second gate has a relatively low aspect ratio, which allows for a reduction in spacing between adjacent gates, while maintaining the required electrical isolation between the gates and contacts that may subsequently be formed.

Abstract: A semiconductor device and method of making such device is presented herein. The method includes disposing a gate layer over a dielectric layer on a substrate and further disposing a cap layer over the gate layer. A first transistor gate is defined having an initial thickness substantially equal to a combined thickness of the cap layer and the gate layer. A first doped region is formed in the substrate adjacent to the first transistor gate. The cap layer is subsequently removed and a second transistor gate is defined having a thickness substantially equal to the thickness of the gate layer. Afterwards, a second doped region is formed in the substrate adjacent to the second transistor gate. The first doped region extends deeper in the substrate than the second doped region, and a final thickness of the first transistor gate is substantially equal to the thickness of the second transistor gate.

Abstract: A method and apparatus for continuously rounded charge trapping layer formation in a flash memory device. The memory device includes a semiconductor layer, including a source/drain region. An isolation region is disposed adjacent to the source/drain region. A first insulator is disposed above the source/drain region. A charge trapping layer is disposed within the first insulator, wherein the charge trapping layer comprises a bulk portion and a first tip and a second tip on either side of said bulk portion, wherein said charge trapping layer extends beyond the width of the source/drain region. A second insulator is disposed above the charge trapping layer. A polysilicon gate structure is disposed above the second insulator, wherein a width of said control gate is wider than the width of said source/drain region.

Abstract: Disclosed herein is a semiconductor device comprising a first dielectric disposed over a channel region of a transistor formed in a substrate and a gate disposed over the first dielectric. The semiconductor device further includes a second dielectric disposed vertically, substantially perpendicular to the substrate, at an edge of the gate, and a spacer disposed proximate to the second dielectric. The spacer includes across-section with a perimeter that includes atop curved portion and a vertical portion substantially perpendicular to the substrate. The perimeter further includes a discontinuity at an interface of the top curved portion with the vertical portion. Further, disclosed herein are methods associated with the fabrication of the aforementioned semiconductor device.

Abstract: A memory string is disclosed including a plurality of core cells serially connected between a source select gate and a drain select gate along a channel. Each core cell includes a wordline separated from the channel by a stack of layers including a charge trapping layer. At least one of the source and drain select gates is a stacked select gate with a plurality of components, including a first component adjacent to the plurality of core cells and a second component separated from the core cells by the first component. The first component includes a wordline separated from the channel by a stack of layers including a charge trapping layer, and a distance between the wordline of the first component and the wordline of a first core cell in the plurality of core cells is substantially the same as distances between each wordline in the plurality of word core cells.

Abstract: A three-dimensional charge trap semiconductor device is constructed with alternating insulating and gate layers stacked over a substrate. During the manufacturing process, a channel hole is formed in the stack and the gate layers are recessed from the channel hole. Using the recessed topography of the gate layers, a charge trap layer can be deposited on the sidewalls of the channel hole and etched, leaving individual discrete charge trap layer sections in each recess. Filling the channel hole with channel material effectively provides a three-dimensional semiconductor device having individual charge trap layer sections for each memory cell.

Abstract: A three-dimensional charge trap semiconductor device is constructed with alternating insulating and gate layers stacked over a substrate. During the manufacturing process, a channel hole is formed in the stack and the gate layers are recessed from the channel hole. Using the recessed topography of the gate layers, a charge trap layer can be deposited on the sidewalls of the channel hole and etched, leaving individual discrete charge trap layer sections in each recess. Filling the channel hole with channel material effectively provides a three-dimensional semiconductor device having individual charge trap layer sections for each memory cell.

Abstract: Disclosed herein is a semiconductor device comprising a first dielectric disposed over a channel region of a transistor formed in a substrate and a gate disposed over the first dielectric. The semiconductor device further includes a second dielectric disposed vertically, substantially perpendicular to the substrate, at an edge of the gate, and a spacer disposed proximate to the second dielectric. The spacer includes a cross-section with a perimeter that includes a top curved portion and a vertical portion substantially perpendicular to the substrate. The perimeter further includes a discontinuity at an interface of the top curved portion with the vertical portion. Further, disclosed herein are methods associated with the fabrication of the aforementioned semiconductor device.

Abstract: A semiconductor device includes a substrate comprising a source region and a drain region, a bit storing element formed on the substrate, a memory gate structure, a first insulating layer formed on the substrate, a second insulating layer formed on the substrate, and a select gate structure formed on the first insulating layer. The second insulating layer is formed on the memory gate structure and the select gate structure and between the memory gate structure and the select gate structure.

Abstract: Embodiments of the present technology are directed toward gate sidewall engineering of field effect transistors. The techniques include formation of a blocking dielectric region and nitridation of a surface thereof. After nitridation of the blocking dielectric region, a gate region is formed thereon and the sidewalls of the gate region are oxidized to round off gate sharp corners and reduce the electrical field at the gate corners.

Abstract: Semiconductor devices and methods of manufacturing thereof are described. According to an example embodiment, a semiconductor device comprises: a substrate comprising a core region and a peripheral region, where the core region is adjacent to the peripheral region; a memory array comprising non-volatile memory cells that are located in the core region of the substrate; a high-voltage control logic comprising high-voltage transistors that are located in the peripheral region of the substrate; and a low-voltage control logic comprising low-voltage transistors that are located in the peripheral region of the substrate.

Abstract: Semiconductor devices and methods of producing the devices are disclosed. The devices are formed by forming a gate structure on a substrate. The gate structure includes a charge trapping dielectric formed between the substrate and a first poly layer. A top dielectric is formed over the poly layer and a sidewall dielectric is formed on a side of the poly layer. A second poly layer is formed over the gate structure such that a portion of the second poly layer includes a vertical portion that is in contact with the sidewall dielectric and a top portion that is in contact with the top dielectric. The top portion of the second poly layer can then be removed through, for instance, planarization.

Abstract: An electronic device includes a substrate with a semiconducting surface having a plurality of fin-type projections coextending in a first direction through a memory cell region and select gate regions. The electronic device further includes a dielectric isolation material disposed in spaces between the projections. In the electronic device, the dielectric isolation material in the memory cell regions have a height less than a height of the projections in the memory cell regions, and the dielectric isolation material in the select gate regions have a height greater than or equal to than a height of the projections in the select gate regions. The electronic device further includes gate features disposed on the substrate within the memory cell region and the select gate regions over the projections and the dielectric isolation material, where the gate features coextend in a second direction transverse to the first direction.

Abstract: Semiconductor devices and methods of producing the devices are disclosed. The devices are formed by forming a gate structure on a substrate. The gate structure includes a charge trapping dielectric formed between the substrate and a first poly layer. A top dielectric is formed over the poly layer and a sidewall dielectric is formed on a side of the poly layer. A second poly layer is formed over the gate structure such that a portion of the second poly layer includes a vertical portion that is in contact with the sidewall dielectric and a top portion that is in contact with the top dielectric. The top portion of the second poly layer can then be removed through, for instance, planarization.

Abstract: Semiconductor devices and the manufacture of such semiconductor devices are described. According to various aspects of the disclosure, a semiconductor device can include a memory region, a first logic region, and a second logic region. A select gate can be formed in the memory region of the device and a first logic gate formed in the logic region. A charge trapping dielectric can then be disposed and removed from a second logic region. A gate conductor layer can then be disposed on the device and etched to define a memory gate on the sidewall of the select gate and a second logic gate in the second logic region.

Abstract: Semiconductor devices and methods of manufacturing such devices are described herein. According to embodiments, a semiconductor device includes a memory gate disposed in a first region of the semiconductor device. The memory gate may include a first gate conductor layer disposed over a charge trapping dielectric. A select gate may be disposed in the first region of the semiconductor device adjacent to a sidewall of the memory gate. A sidewall dielectric may be disposed between the sidewall of the memory gate and the select gate. Additionally, the device may include a logic gate disposed in a second region of the semiconductor device that comprises the first gate conductor layer.

Abstract: A structure and method for providing improved and reliable charge trapping memory device are disclosed herein. A charge trapping field effect transistor (FET) comprising a semiconductor substrate, a doped region in the semiconductor substrate, and a gate structure on the semiconductor substrate and a method of fabricating the same are also discussed. The doped region comprises a first lateral dimension along a first direction. The gate structure comprises a charge trapping dielectric region and a charge trapping conductive region in contact with the charge trapping dielectric region.

Abstract: Semiconductor devices and methods of manufacturing such devices are described herein. According to embodiments, the semiconductor device can be made by forming a dielectric layer at a first region and at a second region of a semiconductor substrate. A gate conductor layer is disposed over the dielectric formed in the first and the second regions of the semiconductor substrate, and the second region is masked. A split gate memory cell is formed in the first region of the semiconductor substrate with a first gate length. The first region is then masked, and the second region is etched to define a logic gate that has a second gate length. The first and second gate lengths can be different.

Abstract: A method for fabricating a memory device with a self-aligned trap layer and rounded active region corners is disclosed. In the present invention, an STI process is performed before any of the charge-trapping and top-level layers are formed. Immediately after the STI process, the sharp corners of the active regions are exposed. Because these sharp corners are exposed at this time, they are available to be rounded through any number of known rounding techniques. Rounding the corners improves the performance characteristics of the memory device. Subsequent to the rounding process, the charge-trapping structure and other layers can be formed by a self-aligned process.