Patent application number | Description | Published |
20080258194 | FLIP FERAM CELL AND METHOD TO FORM SAME - A method of forming an integrated ferroelectric/CMOS structure which effectively separates incompatible high temperature deposition and annealing processes is provided. The method of the present invention includes separately forming a CMOS structure and a ferroelectric delivery wafer. These separate structures are then brought into contact with each and the ferroelectric film of the delivery wafer is bonded to the upper conductive electrode layer of the CMOS structure by using a low temperature anneal step. A portion of the delivery wafer is then removed providing an integrated FE/CMOS structure wherein the ferroelectric capacitor is formed on top of the CMOS structure. The capacitor is in contact with the transistor of the CMOS structure through all the wiring levels of the CMOS structure. | 10-23-2008 |
20090212376 | SEMICONDUCTOR TRANSISTORS HAVING HIGH-K GATE DIELECTRIC LAYERS AND METAL GATE ELECTRODES - A semiconductor structure and a method for forming the same. The semiconductor structure includes (i) a semiconductor substrate which includes a channel region, (ii) first and second source/drain regions on the semiconductor substrate, (iii) a final gate dielectric region, (iv) a final gate electrode region, and (v) a first gate dielectric corner region. The final gate dielectric region (i) includes a first dielectric material, and (ii) is disposed between and in direct physical contact with the channel region and the final gate electrode region. The first gate dielectric corner region (i) includes a second dielectric material that is different from the first dielectric material, (ii) is disposed between and in direct physical contact with the first source/drain region and the final gate dielectric region, (iii) is not in direct physical contact with the final gate electrode region, and (iv) overlaps the final gate electrode region in a reference direction. | 08-27-2009 |
20090309143 | PIXEL SENSOR CELL, METHODS AND DESIGN STRUCTURE INCLUDING OPTICALLY TRANSPARENT GATE - A pixel sensor cell, a method for fabricating or operating the pixel sensor cell and a design structure for fabricating the pixel sensor cell each include a semiconductor substrate that includes a photoactive region separated from a floating diffusion region by a channel region. At least one gate dielectric is located upon the semiconductor substrate at least in-part interposed between the photoactive region and the floating diffusion region, and at least one optically transparent gate is located upon the gate dielectric and at least in-part over the channel region. Preferably, the at least one gate dielectric is also located over the photoactive region and the at least one optically transparent gate is also located at least in-part over the photoactive region, to provide enhanced charge transfer capabilities within the pixel sensor cell, which is typically a CMOS pixel sensor cell. | 12-17-2009 |
20090311822 | PIXEL SENSOR CELL, METHODS AND DESIGN STRUCTURE INCLUDING OPTICALLY TRANSPARENT GATE - A pixel sensor cell, a method for fabricating or operating the pixel sensor cell and a design structure for fabricating the pixel sensor cell each include a semiconductor substrate that includes a photoactive region separated from a floating diffusion region by a channel region. At least one gate dielectric is located upon the semiconductor substrate at least in-part interposed between the photoactive region and the floating diffusion region, and at least one optically transparent gate is located upon the gate dielectric and at least in-part over the channel region. Preferably, the at least one gate dielectric is also located over the photoactive region and the at least one optically transparent gate is also located at least in-part over the photoactive region, to provide enhanced charge transfer capabilities within the pixel sensor cell, which is typically a CMOS pixel sensor cell. | 12-17-2009 |
20100015765 | SHALLOW AND DEEP TRENCH ISOLATION STRUCTURES IN SEMICONDUCTOR INTEGRATED CIRCUITS - A semiconductor structure fabrication method. The method includes providing a semiconductor structure which includes a first semiconductor layer and a dielectric bottom portion in the first semiconductor layer. A second semiconductor layer on the first semiconductor layer is formed. The first and second semiconductor layers include a semiconductor material. A dielectric top portion and a first STI (Shallow Trench Isolation) region are formed in the second semiconductor layer. The dielectric top portion is in direct physical contact with the dielectric bottom portion. | 01-21-2010 |
20100279480 | METHOD OF MAKING SMALL GEOMETRY FEATURES - A method of forming a small geometry feature. The method includes forming a source layer on a top surface of a substrate; forming a mandrel on a top surface of the source layer, the mandrel having a sidewall; sputtering material from the source layer onto the sidewall of the mandrel to form a sidewall layer on the sidewall of the mandrel; and removing the mandrel. Also methods to forming wires and field effect transistors of integrated circuits. | 11-04-2010 |
20100314697 | SEMICONDUCTOR TRANSISTORS HAVING HIGH-K GATE DIELECTRIC LAYERS AND METAL GATE ELECTRODES - A semiconductor structure. The semiconductor structure includes (i) a semiconductor substrate which includes a channel region, (ii) first and second source/drain regions on the semiconductor substrate, (iii) a final gate dielectric region, (iv) a final gate electrode region, and (v) a first gate dielectric corner region. The final gate dielectric region (i) includes a first dielectric material, and (ii) is disposed between and in direct physical contact with the channel region and the final gate electrode region. The first gate dielectric corner region (i) includes a second dielectric material that is different from the first dielectric material, (ii) is disposed between and in direct physical contact with the first source/drain region and the final gate dielectric region, (iii) is not in direct physical contact with the final gate electrode region, and (iv) overlaps the final gate electrode region in a reference direction. | 12-16-2010 |
20110049330 | IMAGE SENSOR, METHOD AND DESIGN STRUCTURE INCLUDING NON-PLANAR REFLECTOR - A solid state image sensor, a method for fabricating the solid state image sensor and a design structure for fabricating the solid state image sensor structure include a substrate that in turn includes a photosensitive region. Also included within solid state image sensor is a non-planar reflector layer located over a side of the photosensitive region and the substrate opposite an incoming radiation side of the photosensitive region and the substrate. The non-planar reflector layer is shaped and positioned to reflect uncaptured incident radiation back into the photosensitive region while avoiding optical cross-talk with an additional photosensitive region laterally separated within the substrate. | 03-03-2011 |
20110062542 | STRUCTURES, DESIGN STRUCTURES AND METHODS OF FABRICATING GLOBAL SHUTTER PIXEL SENSOR CELLS - Pixel sensor cells, method of fabricating pixel sensor cells and design structure for pixel sensor cells. The pixel sensor cells including: a photodiode body in a first region of a semiconductor layer; a floating diffusion node in a second region of the semiconductor layer, a third region of the semiconductor layer between and abutting the first and second regions; and dielectric isolation in the semiconductor layer, the dielectric isolation surrounding the first, second and third regions, the dielectric isolation abutting the first, second and third regions and the photodiode body, the dielectric isolation not abutting the floating diffusion node, portions of the second region intervening between the dielectric isolation and the floating diffusion node. | 03-17-2011 |
20130001727 | IMAGE SENSOR, METHOD AND DESIGN STRUCTURE INCLUDING NON-PLANAR REFLECTOR - A solid state image sensor, a method for fabricating the solid state image sensor and a design structure for fabricating the solid state image sensor structure include a substrate that in turn includes a photosensitive region. Also included within solid state image sensor is a non-planar reflector layer located over a side of the photosensitive region and the substrate opposite an incoming radiation side of the photosensitive region and the substrate. The non-planar reflector layer is shaped and positioned to reflect uncaptured incident radiation back into the photosensitive region while avoiding optical cross-talk with an additional photosensitive region laterally separated within the substrate. | 01-03-2013 |