Patent application number | Description | Published |
20090311845 | One Transistor Memory Cell with Bias Gate - One-transistor (1T) capacitor-less DRAM cells each include a MOS transistor having a bias gate layer that separates a floating body region from a base substrate. The MOS transistor functions as a storage device, eliminating the need of the storage capacitor. Logic “1” is written to and stored in the storage device by causing majority carriers (holes in an NMOS transistor) to accumulate and be held in the floating body region next to the bias gate layer, and is erased by removing the majority carriers from where they are held. | 12-17-2009 |
20100144107 | Semiconductor Memory Device - A memory device comprising a vertical transistor includes a digit line that is directly coupled to the source regions of each memory cell. Because an electrical plug is not used to form a contact between the digit line and the source regions, a number of fabrication steps may be reduced and the possibility for manufacturing defects may also be reduced. In some embodiments, a memory device may include a vertical transistor having gate regions that are recessed from an upper portion of a silicon substrate. With the gate regions recessed from the silicon substrate, the gate regions are spaced further from the source/drain regions and, accordingly, cross capacitance between the gate regions and the source/drain regions may be reduced. | 06-10-2010 |
20100252886 | FIN STRUCTURES AND METHODS OF FABRICATING FIN STRUCTURES - There is provided fin structures and methods for fabricating fin structures. More specifically, fin structures are formed in a substrate. The fin structures may include two fins separated by a channel, wherein the fins may be employed as fins of a field effect transistor. The fin structures are formed below the upper surface of the substrate, and may be formed without utilizing a photolithographic mask to etch the fins. | 10-07-2010 |
20110012182 | Semiconductor Constructions and Transistors, and Methods of Forming Semiconductor Constructions and Transistors - The invention includes a transistor device having a semiconductor substrate with an upper surface. A pair of source/drain regions are formed within the semiconductor substrate and a channel region is formed within the semiconductor substrate and extends generally perpendicularly relative to the upper surface of the semiconductor substrate. A gate is formed within the semiconductor substrate between the pair of the source/drain regions. | 01-20-2011 |
20110171802 | Methods of Making a Semiconductor Memory Device - One-transistor (1T) capacitor-less DRAM cells each include a MOS transistor having a bias gate layer that separates a floating body region from a base substrate. The MOS transistor functions as a storage device, eliminating the need of the storage capacitor. Logic “1” is written to and stored in the storage device by causing majority carriers (holes in an NMOS transistor) to accumulate and be held in the floating body region next to the bias gate layer, and is erased by removing the majority carriers from where they are held. | 07-14-2011 |
20120088349 | METHODS OF FABRICATING FIN STRUCTURES - There is provided fin methods for fabricating fin structures. More specifically, fin structures are formed in a substrate. The fin structures may include two fins separated by a channel, wherein the fins may be employed as fins of a field effect transistor. The fin structures are formed below the upper surface of the substrate, and may be formed without utilizing a photolithographic mask to etch the fins. | 04-12-2012 |
20120231592 | Methods Of Fabricating A Memory Device - A memory device comprising a vertical transistor includes a digit line that is directly coupled to the source regions of each memory cell. Because an electrical plug is not used to form a contact between the digit line and the source regions, a number of fabrication steps may be reduced and the possibility for manufacturing defects may also be reduced. In some embodiments, a memory device may include a vertical transistor having gate regions that are recessed from an upper portion of a silicon substrate. With the gate regions recessed from the silicon substrate, the gate regions are spaced further from the source/drain regions and, accordingly, cross capacitance between the gate regions and the source/drain regions may be reduced. | 09-13-2012 |
20130026600 | FORMING AIR GAPS IN MEMORY ARRAYS AND MEMORY ARRAYS WITH AIR GAPS THUS FORMED - Methods of forming air gaps in memory arrays and memory arrays with air gaps thus formed are disclosed. One such method may include forming an isolation region, having a first dielectric, through a charge-storage structure that is over a semiconductor, the isolation region extending into the semiconductor; forming a second dielectric over the isolation region and charge-storage structure; and forming an air gap in the isolation region so that the air gap passes through the charge-storage structure and so that a thickness of the first dielectric is between the air gap and the second dielectric. | 01-31-2013 |
20130168756 | SOURCE/DRAIN ZONES WITH A DELECTRIC PLUG OVER AN ISOLATION REGION BETWEEN ACTIVE REGIONS AND METHODS - Devices, memory arrays, and methods are disclosed. In an embodiment, one such device has a source/drain zone that has first and second active regions, and an isolation region and a dielectric plug between the first and second active regions. The dielectric plug may extend below upper surfaces of the first and second active regions and may be formed of a dielectric material having a lower removal rate than a dielectric material of the isolation region for a particular isotropic removal chemistry. | 07-04-2013 |
20130178025 | Methods Of Fabricating A Memory Device - A memory device comprising a vertical transistor includes a digit line that is directly coupled to the source regions of each memory cell. Because an electrical plug is not used to form a contact between the digit line and the source regions, a number of fabrication steps may be reduced and the possibility for manufacturing defects may also be reduced. In some embodiments, a memory device may include a vertical transistor having gate regions that are recessed from an upper portion of a silicon substrate. With the gate regions recessed from the silicon substrate, the gate regions are spaced further from the source/drain regions and, accordingly, cross capacitance between the gate regions and the source/drain regions may be reduced. | 07-11-2013 |
20140027832 | FORMING AIR GAPS IN MEMORY ARRAYS AND MEMORY ARRAYS WITH AIR GAPS THUS FORMED - A memory array has first and second memory cells over a semiconductor and an isolation region extending into the semiconductor. The isolation region includes an air gap between charge-storage structures of the first and second memory cells and a thickness of dielectric over the air gap and contained between the first and second memory cells. | 01-30-2014 |
20140239303 | SEMICONDUCTOR DEVICES INCLUDING WISX AND METHODS OF FABRICATION - Some embodiments include a semiconductor device having a stack structure including a plurality of alternating tiers of dielectric material and poly-silicon formed on a substrate. Such a semiconductor device may further include at least one opening having a high aspect ratio and extending into the stack structure to a level adjacent the substrate, a first poly-silicon channel formed in a lower portion of the opening adjacent the substrate, a second poly-silicon channel formed in an upper portion of the opening, and WSiX material disposed between the first poly-silicon channel and the second poly-silicon channel in the opening. The WSiX material is adjacent to the substrate, and can be used as an etch-landing layer and a conductive contact to contact both the first poly-silicon channel and the second poly-silicon channel in the opening. Other embodiments include methods of making semiconductor devices. | 08-28-2014 |
20140346613 | METHODS OF FABRICATING FIN STRUCTURES - There is provided fin methods for fabricating fin structures. More specifically, fin structures are formed in a substrate. The fin structures may include two fins separated by a channel, wherein the fins may be employed as fins of a field effect transistor. The fin structures are formed below the upper surface of the substrate, and may be formed without utilizing a photolithographic mask to etch the fins. | 11-27-2014 |
20150064871 | Forming Source/Drain Zones with a Delectric Plug Over an Isolation Region Between Active Regions - An embodiment includes forming an isolation region between first and second active regions in a semiconductor, forming an opening between the first and second active regions by removing a portion of the isolation region, and forming a dielectric plug within the opening so that the dielectric plug is between the first and second active regions and so that a portion of the dielectric plug extends below upper surfaces of the first and second active regions. The dielectric plug may be formed of a dielectric material having a lower removal rate than a dielectric material of the isolation region for a particular isotropic removal chemistry. | 03-05-2015 |