Patent application number | Description | Published |
20100207191 | METHOD AND DEVICE EMPLOYING POLYSILICON SCALING - A memory and method of manufacture employing word line scaling. A layered stack, including a charge trapping component and a core polysilicon layer, is formed on a core section and a peripheral section of a substrate. A portion of the layered stack, including the core polysilicon layer is then removed from the peripheral section. A peripheral polysilicon layer, which is thicker than the core polysilicon layer of the layered stack, is next formed on the layered stack and the peripheral section. The layered stack is then isolated from the peripheral polysilicon layer by removing a portion of the peripheral polysilicon layer from the core section, and polysilicon lines are patterned in the isolated layered stack. | 08-19-2010 |
20110220981 | NON-VOLATILE FINFET MEMORY DEVICE AND MANUFACTURING METHOD THEREOF - Methods for fabricating an electronic device and electronic devices therefrom are provided. A method includes forming one or more masking layers on a semiconducting surface of a substrate and forming a plurality of dielectric isolation features and a plurality of fin-type projections using the masking layer. The method also includes processing the masking layers and the plurality of fin-type projections to provide an inverted T-shaped cross-section for the plurality of fin-type projections that includes a distal extension portion and a proximal base portion. The method further includes forming a plurality of bottom gate layers on the distal extension portion and forming a plurality of control gate layers on the plurality of dielectric isolation features and the plurality of bottom gate layers. | 09-15-2011 |
20110221006 | NAND ARRAY SOURCE/DRAIN DOPING SCHEME - An electronic device includes a substrate having isolation features defining active regions coextending over a surface of the substrate. The device also includes coextending line patterns crossing over the active regions, including string and ground selection lines and word lines between the string and ground selection lines. The device further includes first implant regions of a first conductivity type in the active regions between the word lines and having a first carrier concentration. The device further includes second implant regions of the first conductivity type in the active regions between edge ones of the word lines and an adjacent one of the string selection line and the ground selection line. In the device, the second implant region includes a low doping portion abutting the edge word lines and a high doping portion spaced from the edge word line by the low doping portion and having a second carrier concentration greater than the first carrier concentration. | 09-15-2011 |
20110233647 | METHODS FOR FORMING A MEMORY CELL HAVING A TOP OXIDE SPACER - Methods for fabricating a semiconductor memory cell that has a spacer layer are disclosed. A method includes forming a plurality of source/drain regions in a substrate where the plurality of source/drain regions are formed between trenches, forming a first oxide layer above the plurality of source/drain regions and in the trenches, forming a charge storage layer above the oxide layer and separating the charge storage layer in the trenches where a space is formed between separated portions of the charge storage layer. The method further includes forming a spacer layer to fill the space between the separated portions of the charge storage layer and to rise a predetermined distance above the space. A second oxide layer is formed above the charge storage layer and the spacer layer and a polysilicon layer is formed above the second oxide layer. | 09-29-2011 |
20120056260 | METHOD AND DEVICE EMPLOYING POLYSILICON SCALING - A memory and method of manufacture employing word line scaling. A layered stack, including a charge trapping component and a core polysilicon layer, is formed on a core section and a peripheral section of a substrate. A portion of the layered stack, including the core polysilicon layer is then removed from the peripheral section. A peripheral polysilicon layer, which is thicker than the core polysilicon layer of the layered stack, is next formed on the layered stack and the peripheral section. The layered stack is then isolated from the peripheral polysilicon layer by removing a portion of the peripheral polysilicon layer from the core section, and polysilicon lines are patterned in the isolated layered stack. | 03-08-2012 |
20120139023 | METHOD AND APPARATUS FOR NAND MEMORY WITH RECESSED SOURCE/DRAIN REGION - A method and apparatus for a flash memory is provided. A NAND flash memory array includes a cell body, a first selective gate, and a first edge line. The cell body includes recessed doped source/drain region between the first selective gate and the first edge word line. | 06-07-2012 |
20120168847 | MEMORY WITH EXTENDED CHARGE TRAPPING LAYER - A memory array includes a plurality of bit lines and a plurality of word lines, a gate region, and a charge trapping layer. The charge trapping layer is wider than a word line; the charge trapping layer is extended beyond the edge of the gate region to facilitate capturing and removing charges. | 07-05-2012 |
20120181591 | NON-VOLATILE FINFET MEMORY ARRAY AND MANUFACTURING METHOD THEREOF - 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. | 07-19-2012 |
20120181601 | METHODS FOR FORMING A MEMORY CELL HAVING A TOP OXIDE SPACER - Methods for fabricating a semiconductor memory cell that has a spacer layer are disclosed. A method includes forming a plurality of source/drain regions in a substrate where the plurality of source/drain regions are formed between trenches, forming a first oxide layer above the plurality of source/drain regions and in the trenches, forming a charge storage layer above the oxide layer and separating the charge storage layer in the trenches where a space is formed between separated portions of the charge storage layer. The method further includes forming a spacer layer to fill the space between the separated portions of the charge storage layer and to rise a predetermined distance above the space. A second oxide layer is formed above the charge storage layer and the spacer layer and a polysilicon layer is formed above the second oxide layer. | 07-19-2012 |
20140148001 | NON-VOLATILE FINFET MEMORY DEVICE AND MANUFACTURING METHOD THEREOF - Methods for fabricating an electronic device and electronic devices therefrom are provided. A method includes forming one or more masking layers on a semiconducting surface of a substrate and forming a plurality of dielectric isolation features and a plurality of fin-type projections using the masking layer. The method also includes processing the masking layers and the plurality of fin-type projections to provide an inverted T-shaped cross-section for the plurality of fin-type projections that includes a distal extension portion and a proximal base portion. The method further includes forming a plurality of bottom gate layers on the distal extension portion and forming a plurality of control gate layers on the plurality of dielectric isolation features and the plurality of bottom gate layers. | 05-29-2014 |
20140167128 | Memory Gate Landing Pad Made From Dummy Features - Embodiments described herein generally relate to landing gate pads for contacts and manufacturing methods therefor. A bridge is formed between two features to allow a contact to be disposed, at least partially, on the bridge. Landing the contact on the bridge avoids additional manufacturing steps to create a target for a contact. | 06-19-2014 |
20140167135 | Process Charging Protection for Split Gate Charge Trapping Flash - A semiconductor device and method of making such device is presented herein. The semiconductor device includes a plurality of memory cells, a plurality of p-n junctions, and a metal trace of a first metal layer. Each of the plurality of memory cells includes a first gate disposed over a first dielectric, a second gate disposed over a second dielectric and adjacent to a sidewall of the first gate, a first doped region in the substrate adjacent to the first gate, and a second doped region in the substrate adjacent to the second gate. The plurality of p-n junctions are electrically isolated from the doped regions of each memory cell. The metal trace extends along a single plane between a via to the second gate of at least one memory cell in the plurality of memory cells, and a via to a p-n junction within the plurality of p-n junctions. | 06-19-2014 |
20140167137 | High Voltage Gate Formation - Embodiments described herein generally relate to methods of manufacturing charge-trapping memory by patterning the high voltage gates before other gates are formed. One advantage of such an approach is that a thin poly layer may be used to form memory and low voltage gates while protecting high voltage gates from implant penetration. One approach to accomplishing this is to dispose the layer of poly, and then dispose a mask and a thick resist to pattern the high voltage gates. In this manner, the high voltage gates are formed before either the low voltage gates or the memory cells. | 06-19-2014 |
20140167139 | Integrated Circuits With Non-Volatile Memory and Methods for Manufacture - 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. | 06-19-2014 |
20140167140 | Memory First Process Flow and Device - 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. | 06-19-2014 |
20140167141 | Charge Trapping Split Gate Embedded Flash Memory and Associated Methods - Semiconductor devices and methods of manufacturing such devices are described herein. According to embodiments, the semiconductor device can be made by forming an 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. | 06-19-2014 |
20140167142 | Use Disposable Gate Cap to Form Transistors, and Split Gate Charge Trapping Memory Cells - 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. | 06-19-2014 |
20140167220 | THREE DIMENSIONAL CAPACITOR - Integrated capacitor structures and methods for fabricating same are provided. In an embodiment, the integrated capacitor structures exploit the capacitance that can be formed in a plane that is perpendicular to that of the substrate, resulting in three-dimensional capacitor structures. This allows for integrated capacitor structures with higher capacitance to be formed over relatively small substrate areas. Embodiments are suitable for use by charge pumps and can be fabricated to have more or less capacitance as desired by the application. | 06-19-2014 |
20140170843 | Charge Trapping Split Gate Device and Method of Fabricating Same - Embodiments provide a split gate device, methods for fabricating a split gate device, and integrated methods for fabricating a split gate device and a periphery device. In an embodiment, the split gate device is a charge trapping split gate device, which includes a charge trapping layer. In another embodiment, the split gate device is a non-volatile memory cell, which can be formed according to embodiments as standalone or embedded with a periphery device. | 06-19-2014 |
20140332876 | HIGH VOLTAGE GATE FORMATION - Embodiments described herein generally relate to methods of manufacturing charge-trapping memory by patterning the high voltage gates before other gates are formed. One advantage of such an approach is that a thin poly layer may be used to form memory and low voltage gates while protecting high voltage gates from implant penetration. One approach to accomplishing this is to dispose the layer of poly, and then dispose a mask and a thick resist to pattern the high voltage gates. In this manner, the high voltage gates are formed before either the low voltage gates or the memory cells. | 11-13-2014 |
20140370698 | Non-Volatile Finfet Memory Array and Manufacturing Method Thereof - 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. | 12-18-2014 |
20150031197 | Integrated Circuits with Non-Volatile Memory and Methods for Manufacture - 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. | 01-29-2015 |