| Patent application number | Description | Published |
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| 20090035886 | PREDOPED TRANSFER GATE FOR A CMOS IMAGE SENSOR - A novel CMOS image sensor Active Pixel Sensor (APS) cell structure and method of manufacture. Particularly, a CMOS image sensor APS cell having a predoped transfer gate is formed that avoids the variations of V | 02-05-2009 |
| 20090101941 | WRAPPED GATE JUNCTION FIELD EFFECT TRANSISTOR - A wrapped gate junction field effect transistor (JFET) with at least one semiconductor channel having a first conductivity type doping is provided. Both sidewalls of each of the at least one semiconductor channel laterally abuts a side gate region having a second conductivity type doping, which is the opposite of the first conductivity doping. Further, the at least one semiconductor channel vertically abuts a top gate region and at least one bottom gate region, both having the second conductivity type doping. The gate electrode, which comprises side gate region, the top gate region, and at least one bottom gate regions, wraps around each of the at least one semiconductor channel to provide tight control of the current, i.e., a low off-current, through the at least one semiconductor channel. By employing multiple channels, the JFET may provide a high on-current. | 04-23-2009 |
| 20100230729 | PIXEL SENSOR CELL INCLUDING LIGHT SHIELD - CMOS image sensor pixel sensor cells, methods for fabricating the pixel sensor cells and design structures for fabricating the pixel sensor cells are designed to allow for back side illumination in global shutter mode by providing light shielding from back side illumination of at least one transistor within the pixel sensor cells. In a first particular generalized embodiment, a light shielding layer is located and formed interposed between a first semiconductor layer that includes a photoactive region and a second semiconductor layer that includes the at least a second transistor, or a floating diffusion, that is shielded by the light blocking layer. In a second generalized embodiment, a thin film transistor and a metal-insulator-metal capacitor are used in place of a floating diffusion, and located shielded in a dielectric isolated metallization stack over a carrier substrate | 09-16-2010 |
| Patent application number | Description | Published |
|---|
| 20080265422 | STRUCTURE FOR CHARGE DISSIPATION DURING FABRICATION OF INTEGRATED CIRCUITS AND ISOLATION THEREOF - A structure for dissipating charge during fabrication of an integrated circuit. The structure includes: a substrate contact in a semiconductor substrate; one or more wiring levels over the substrate; one or more electrically conductive charge dissipation structures extending from a top surface of an uppermost wiring level of the one or more wiring levels through each lower wiring level of the one or more wiring levels to and in electrical contact with the substrate contact; and circuit structures in the substrate and in the one or more wiring layers, the charge dissipation structures not electrically contacting any the circuit structures in any of the one or more wiring levels, the one or more charge dissipation structures dispersed between the circuit structures. | 10-30-2008 |
| 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 |
| 20100244132 | Methods for Normalizing Strain in Semiconductor Devices and Strain Normalized Semiconductor Devices - A method of normalizing strain in semiconductor devices and normalized strain semiconductor devices. The method includes: forming first and second field effect transistors of an integrated circuit; forming a stress layer over the first and second field effect transistors, the stress layer inducing strain in channel regions of the first and second field effect transistors; and selectively thinning the stress layer over at least a portion of the second field effect transistor. | 09-30-2010 |
| 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 |
