Patent application number | Description | Published |
20090155992 | HIGH K STACK FOR NON-VOLATILE MEMORY - A memory device may include a source region and a drain region formed in a substrate and a channel region formed in the substrate between the source and drain regions. The memory device may further include a first oxide layer formed over the channel region, the first oxide layer having a first dielectric constant, and a charge storage layer formed upon the first oxide layer. The memory device may further include a second oxide layer formed upon the charge storage layer, a layer of dielectric material formed upon the second oxide layer, the dielectric material having a second dielectric constant that is greater than the first dielectric constant, and a gate electrode formed upon the layer of dielectric material. | 06-18-2009 |
20120241871 | INTEGRATING TRANSISTORS WITH DIFFERENT POLY-SILICON HEIGHTS ON THE SAME DIE - A method of fabricating an integrated circuit including a first region and a second region each having different poly-silicon gate structures is provided. The method includes depositing a first poly-silicon layer over the first and the second region and depositing, within the second region, an oxide layer over the first poly-silicon layer. A second poly-silicon layer is deposited over the first poly-silicon layer and the oxide region. A portion of the second poly-silicon layer that lies over the oxide region is then stripped away. | 09-27-2012 |
20130023101 | METHOD AND MANUFACTURE FOR EMBEDDED FLASH TO ACHIEVE HIGH QUALITY SPACERS FOR CORE AND HIGH VOLTAGE DEVICES AND LOW TEMPERATURE SPACERS FOR HIGH PERFORMANCE LOGIC DEVICES - A method and manufacture for memory device fabrication is provided. Spacer formation and junction formation is performed on both: a memory cell region in a core section of a memory device in fabrication, and a high-voltage device region in a periphery section of the memory device in fabrication. The spacer formation and junction formation on both the memory cell region and the high-voltage device region includes performing a rapid thermal anneal. After performing the spacer formation and junction formation on both the memory cell region and the high-voltage device region, spacer formation and junction formation is performed on a low-voltage device region in the periphery section. | 01-24-2013 |
20140015138 | Leakage Reducing Writeline Charge Protection Circuit - Methods and systems of fabricating a wordline protection structure are described. As described, the wordline protection structure includes a polysilicon structure formed adjacent to a memory core region. The polysilicon structure includes first doped region positioned on a core side of the polysilicon structure and a second doped region positioned on a spine side of the polysilicon structure. An un-doped region positioned between the first and second doped regions. A conductive layer is formed on top of the polysilicon structure and arranged so that it does not contact the un-doped region at either the transition between the first doped region and the un-doped region or the second doped region and un-doped region. | 01-16-2014 |
20140117435 | INTEGRATING TRANSISTORS WITH DIFFERENT POLY-SILICON HEIGHTS ON THE SAME DIE - A method of fabricating an integrated circuit including a first region and a second region each having different poly-silicon gate structures is provided. The method includes depositing a first poly-silicon layer over the first and the second region and depositing, within the second region, an oxide layer over the first poly-silicon layer. A second poly-silicon layer is deposited over the first poly-silicon layer and the oxide region. A portion of the second poly-silicon layer that lies over the oxide region is then stripped away. | 05-01-2014 |
20140209993 | Non-Volatile Memory With Silicided Bit Line Contacts - An approach to use silicided bit line contacts that do not short to the underlying substrate in memory devices. The approach provides for silicide formation in the bit line contact area, using a process that benefits from being self-aligned to the oxide-nitride-oxide (ONO) nitride edges. A farther benefit of the approach is that the bit line contact implant and rapid temperature anneal process can be eliminated. This approach is applicable to embedded flash, integrating high density devices and advanced logic processes. | 07-31-2014 |
20140312409 | SYSTEM AND METHOD FOR MANUFACTURING SELF-ALIGNED STI WITH SINGLE POLY - 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. | 10-23-2014 |
20150017795 | Non-Volatile Memory With Silicided Bit Line Contacts - An approach to use silicided bit line contacts that do not short to the underlying substrate in memory devices. The approach provides for silicide formation in the bit line contact area, using a process that benefits from being self-aligned to the oxide-nitride-oxide (ONO) nitride edges. A further benefit of the approach is that the bit line contact implant and rapid temperature anneal process can be eliminated. This approach is applicable to embedded flash, integrating high density devices and advanced logic processes. | 01-15-2015 |