Abstract: A method of preventing the formation of cracks on the backside of a silicon (Si) semiconductor chip or wafer during the processing thereof. Also provided is a method for inhibiting the propagation of cracks, which have already formed in the backside of a silicon chip during the processing thereof and prior to the joining thereto of a substrate during the fabrication of an electronic package. The methods entail either treating the backside with a wet etch, or alternatively, applying a protective film layer thereon prior to forming an electronic package incorporating the chip or wafer.

Abstract: The invention provides vertically-stacked photodiodes buried in a semiconductor material that are isolated and selectively contacted by deep trenches. One embodiment of the invention provides a pixel sensor comprising: a plurality of photosensitive elements formed in a substrate, each photosensitive element being adapted to generate photocharges in response to electromagnetic radiation; and a plurality of photocharge transfer devices, each photocharge transfer device being coupled to at least one of the plurality of photosensitive elements.

Abstract: A novel CMOS image sensor cell structure and method of manufacture. The imaging sensor comprises a substrate having an upper surface, a gate comprising a dielectric layer formed on the substrate and a gate conductor formed on the gate dielectric layer, a collection well layer of a first conductivity type formed below a surface of the substrate adjacent a first side of the gate conductor, a pinning layer of a second conductivity type formed atop the collection well at the substrate surface, and a diffusion region of a first conductivity type formed adjacent a second side of the gate conductor, the gate conductor forming a channel region between the collection well layer and the diffusion region. A portion of the bottom of the gate conductor is recessed below the surface of the substrate.

Abstract: A test structure (200, 200?) having an array (224) of test devices (220) for detecting and studying defects that can occur in an integrated circuit device, e.g., a transistor (144), due to the relative positioning of one component (100) of the device with respect to another component (108) of the device. The test devices in the array are of a like kind, but vary in their configuration. The differences in the configurations are predetermined and selected with the intent of forcing defects to occur within at least some of the test devices. During testing, the responses of the test devices are sensed so as to determine whether or not a defect has occurred in any one or more of the test devices. If a defective test device is detected, the corresponding wafer (204) may be subjected to physical failure analysis for yield learning.

Abstract: A method of forming a pixel sensor cell structure. The method of forming the pixel cell comprises forming a doped layer adjacent to a first side of a transfer gate structure for coupling a collection well region and a channel region. Potential barrier interference to charge transfer caused by a pinning layer is reduced.

Abstract: A method of preventing the formation of cracks on the backside of a silicon (Si) semiconductor chip or wafer during the processing thereof. Also provided is a method for inhibiting the propagation of cracks, which have already formed in the backside of a silicon chip during the processing thereof and prior to the joining thereto of a substrate during the fabrication of an electronic package. The methods entail either treating the backside with a wet etch, or alternatively, applying a protective film layer thereon prior to forming an electronic package incorporating the chip or wafer.

Abstract: A method of preventing the formation of cracks on the backside of a silicon (Si) semiconductor chip or wafer during the processing thereof. Also provided is a method for inhibiting the propagation of cracks, which have already formed in the backside of a silicon chip during the processing thereof and prior to the joining thereto of a substrate during the fabrication of an electronic package. The methods entail either treating the backside with a wet etch, or alternatively, applying a protective film layer thereon prior to forming an electronic package incorporating the chip or wafer.

Abstract: A method of preventing the formation of cracks on the backside of a silicon (Si) semiconductor chip or wafer during the processing thereof. Also provided is a method for inhibiting the propagation of cracks, which have already formed in the backside of a silicon chip during the processing thereof and prior to the joining thereto of a substrate during the fabrication of an electronic package. The methods entail either treating the backside with a wet etch, or alternatively, applying a protective film layer thereon prior to forming an electronic package incorporating the chip or wafer.

Abstract: A novel image sensor cell structure and method of manufacture. The imaging sensor comprises a substrate, a gate comprising a dielectric layer and gate conductor formed on the dielectric layer, a collection well layer of a first conductivity type formed below a surface of the substrate adjacent a first side of the gate conductor, a pinning layer of a second conductivity type formed atop the collection well at the substrate surface, and a diffusion region of a first conductivity type formed adjacent a second side of the gate conductor, the gate conductor forming a channel region between the collection well layer and the diffusion region. Part of the gate conductor bottom is recessed below the surface of the substrate. Preferably, a portion of the gate conductor is recessed at or below a bottom surface of the pinning layer to a depth such that the collection well intersects the channel region.

Abstract: A pixel sensor cell structure and method of manufacture. The pixel cell comprises a doped layer formed adjacent to a first side of a transfer gate structure for coupling a collection well region and a channel region. Potential barrier interference to charge transfer caused by a pinning layer is reduced.

Abstract: A silicon on insulator transistor is disclosed which has a Schottky contact to the body. The Schottky contact may be formed on the source and/or drain side of the gate conductor. A spacer, with at least a part thereof being disposable, is formed on the sidewalls of the gate conductor. Extension regions are provided in the substrate which extend under the spacer and the gate conductor. Source and drain diffusion regions are implanted into the substrate adjacent to the extension regions. The disposable part of the spacer is then removed to expose a portion of the extension region. A metal layer is formed at least in the extension regions, resulting in the Schottky contact.

Abstract: The present invention provides a process for fabricating a metal oxide semiconductor field effect transistor (MOSFET) having a double-gate and a double-channel wherein the gate region is self-aligned to the channel regions and the source/drain diffusion junctions. The present invention also relates to the FIN MOSFFET structure which is formed using method of the present invention.

Abstract: A method and apparatus are provided for forming a silicide on a semiconductor substrate by integrating under a constant vacuum the processes of removing an oxide from a surface of a semiconductor substrate and depositing a metal on the cleaned surface without exposing the cleaned surface to air. The method and apparatus of the present invention eliminates the exposure of the cleaned substrate to air between the oxide removal and metal deposition steps. This in-situ cleaning of the silicon substrate prior to cobalt deposition provides a cleaner silicon substrate surface, resulting in enhanced formation of cobalt silicide when the cobalt layer is annealed.

Abstract: The present invention provides a process for fabricating a metal oxide semiconductor field effect transistor (MOSFET) having a double-gate and a double-channel wherein the gate region is self-aligned to the channel regions and the source/drain diffusion junctions. The present invention also relates to the FIN MOSFFET structure which is formed using method of the present invention.

Abstract: A chip-on-chip module and associated method of formation. First and second semiconductor chips are coupled together. The first chip comprises a first wiring layer and a first electrically conductive substrate on first and second sides, respectively, of the first chip. A supply voltage VDD is adapted to be electrically coupled to the second side of the first chip. The second chip comprises a second wiring layer and a second electrically conductive substrate on first and second sides, respectively, of the second chip. A ground voltage GND is adapted to be electrically coupled to the second side of the second chip. The first side of the first chip is electrically coupled to the first side of the second chip. The supply voltage VDD and the ground voltage GND are adapted to provide power to the first and second chips.

Abstract: The present invention provides a process for fabricating a metal oxide semiconductor field effect transistor (MOSFET) having a double-gate and a double-channel wherein the gate region is self-aligned to the channel regions and the source/drain diffusion junctions. The present invention also relates to the FIN MOSFFET structure which is formed using method of the present invention.

Abstract: A double gated silicon-on-insulator (SOI) MOSFET is fabricated by using a mandrel shallow trench isolation formation process, followed by a damascene gate. The double gated MOSFET features narrow diffusion lines defined sublithographically or lithographically and shrunk, damascene process defined by an STI-like mandrel process. The double gated SOI MOSFET increases current drive per layout width and provides low out conductance.

Abstract: A chip-on-chip module and associated method of formation. First and second semiconductor chips are coupled together. The first chip comprises a first wiring layer and a first electrically conductive substrate on first and second sides, respectively, of the first chip. A supply voltage VDD is adapted to be electrically coupled to the second side of the first chip. The second chip comprises a second wiring layer and a second electrically conductive substrate on first and second sides, respectively, of the second chip. A ground voltage GND is adapted to be electrically coupled to the second side of the second chip. The first side of the first chip is electrically coupled to the first side of the second chip. The supply voltage VDD and the ground voltage GND are adapted to provide power to the first and second chips.

Abstract: A method and structure for fabricating a semiconductor wafer that may be used to monitor the temperature distribution across a wafer surface. A substrate that includes a semiconductor material and a first dopant, has an amorphous layer formed from a top portion of the substrate, and the amorphous layer is doped with a second dopant of polarity opposite to a polarity of the first dopant. Heating of the wafer at 450 to 625 degree C. recrystallizes a portion of the amorphous layer that is adjacent to the substrate at a recrystallization rate that depends on a local temperature on the wafer surface. The measured spatial distribution of sheet resistance may be utilized to readjust the spatial distribution of heat input to another wafer in order to achieve a more uniform temperature across the other wafer's surface.

Abstract: A chip-on-chip module and associated method of formation. First and second semiconductor chips are coupled together. The first chip comprises a first wiring layer and a first electrically conductive substrate on first and second sides, respectively, of the first chip. A supply voltage VDD is adapted to be electrically coupled to the second side of the first chip. The second chip comprises a second wiring layer and a second electrically conductive substrate on first and second sides, respectively, of the second chip. A ground voltage GND is adapted to be electrically coupled to the second side of the second chip. The first side of the first chip is electrically coupled to the first side of the second chip. The supply voltage VDD and the ground voltage GND are adapted to provide power to the first and second chips.