Abstract: An image sensor includes a pixel array, a bit line, a supplemental capacitance node line, and a control circuit. The pixel array includes a plurality of pixel cells each including a floating diffusion (“FD”) node and a photosensitive element coupled to selectively transfer image charge to the FD node. The bit line is coupled to selectively conduct image data output from a first group of the pixel cells. The supplemental capacitance node line is coupled to the FD node of a second group of the pixel cells different from the first group. The control circuit is coupled to the supplemental capacitance node line to selectively increase the potential at the FD node of each of the pixel cells of the second group by selectively asserting a FD boost signal on the supplemental capacitance node line.

Abstract: Embodiments of a process for forming a photodetector region in a CMOS pixel by dopant implantation, the process comprising masking a photodetector area of a surface of a substrate for formation of the photodetector region, positioning the substrate at a plurality of twist angles, and at each of the plurality of twist angles, directing dopants at the photodetector area at a selected tilt angle. Embodiments of a CMOS pixel comprising a photodetector region formed in a substrate, the photodetector region comprising overlapping first and second dopant implants, wherein the overlap region has a different dopant concentration than the non-overlapping parts of the first and second implants, a floating diffusion formed in the substrate, and a transfer gate formed on the substrate between the photodetector and the transfer gate. Other embodiments are disclosed and claimed.

Abstract: A color image sensor is disclosed. The color image sensor includes a pixel array including a color filter array (“CFA”) overlaying an array of photo-sensors for acquiring a color image. The CFA includes first color filter elements of a first color overlaying a first group of the photo-sensors and second color filter elements of a second color overlaying a second group of the photo-sensors. The first color filter elements contribute to a first color channel of the color image and the second color filter elements contribute to a second color channel of the color image. The color image sensor further includes a color combiner unit coupled to combine the first color channel with the second color channel to generate a third color channel of the color image based on the first and second color channels. An output port is coupled to the pixel array to output the color image having three color channels including the first, second, and third color channels.

Abstract: A backside illuminated (“BSI”) complementary metal-oxide semiconductor (“CMOS”) image sensor includes a photosensitive region disposed within a semiconductor layer and a stress adjusting layer. The photosensitive region is sensitive to light incident on a backside of the BSI CMOS image sensor to collect an image charge. The stress adjusting layer is disposed on a backside of the semiconductor layer to establish a stress characteristic that encourages photo-generated charge carriers to migrate towards the photosensitive region.

Abstract: The invention involves the integration of curved micro-mirrors over a photodiode active area (collection area) in a CMOS image sensor (CIS) process. The curved micro-mirrors reflect light that has passed through the collection area back into the photo diode. The curved micro-mirrors are best implemented in a backside illuminated device (BSI).

Abstract: Forming a doped isolation region in a substrate during manufacture of an image sensor. A method of an aspect includes forming a hardmask layer over the substrate, and forming a photoresist layer over the hardmask layer. An opening is formed in the photoresist layer over an intended location of the doped isolation region. An opening is etched in the hardmask layer by exposing the hardmask layer to one or more etchants through the opening. The opening in the hardmask layer may have a width of less than 0.4 micrometers. The doped isolation region may be formed in the substrate beneath the opening in the hardmask layer by performing a dopant implantation that introduces dopant through the opening in the hardmask layer. The method of an aspect may include forming sidewall spacers on sidewalls of the opening in the hardmask layer and using the sidewall spacers as a dopant implantation mask.

Abstract: An image sensor pixel includes a substrate, a first epitaxial layer, a collector layer, a second epitaxial layer and a light collection region. The substrate is doped to have a first conductivity type. The first epitaxial layer is disposed over the substrate and doped to have the first conductivity type as well. The collector layer is selectively disposed over at least a portion of the first epitaxial layer and doped to have a second conductivity type. The second epitaxial layer is disposed over the collector layer and doped to have the first conductivity type. The light collection region collects photo-generated charge carriers and is disposed within the second epitaxial layer. The light collection region is also doped to have the second conductivity type.

Abstract: A backside illuminated imaging sensor includes a semiconductor layer and an infrared detecting layer. The semiconductor layer has a front surface and a back surface. An imaging pixel includes a photodiode region formed within the semiconductor layer. The infrared detecting layer is disposed above the front surface of the semiconductor layer to receive infrared light that propagates through the imaging sensor from the back surface of the semiconductor layer.

Abstract: A technique for fabricating an image sensor including a pixel circuitry region and a peripheral circuitry region includes fabricating front side components on a front side of the image sensor. A dopant layer is implanted on a backside of the image sensor. A anti-reflection layer is formed on the backside and covers a first portion of the dopant layer under the pixel circuitry region while exposing a second portion of the dopant layer under the peripheral circuitry region. The first portion of the dopant layer is laser annealed from the backside of the image sensor through the anti-reflection layer. The anti-reflection layer increases a temperature of the first portion of the dopant layer during the laser annealing.

Abstract: An image sensor includes at least one photosensitive element disposed in a semiconductor substrate. Metal conductors may be disposed on the semiconductor substrate. A filter may be disposed between at least two individual metal conductors and a micro-lens may be disposed on the filter. There may be insulator material disposed between the metal conductors and the semiconductor substrate and/or between individual metal conductors. The insulator material may be removed so that the filter may be disposed on the semiconductor substrate.

Abstract: A technique for fabricating an image sensor including a pixel circuitry region and a peripheral circuitry region includes fabricating front side components on a front side of the image sensor. A dopant layer is implanted on a backside of the image sensor. A anti-reflection layer is formed on the backside and covers a first portion of the dopant layer under the pixel circuitry region while exposing a second portion of the dopant layer under the peripheral circuitry region. The first portion of the dopant layer is laser annealed from the backside of the image sensor through the anti-reflection layer. The anti-reflection layer increases a temperature of the first portion of the dopant layer during the laser annealing.

Abstract: Embodiments of the present invention are directed to an image sensor having pixel transistors and peripheral transistors disposed in a silicon substrate. For some embodiments, a protective coating is disposed on the peripheral transistors and doped silicon is epitaxially grown on the substrate to form lightly-doped drain (LDD) areas for the pixel transistors. The protective oxide may be used to prevent epitaxial growth of silicon on the peripheral transistors during formation of the LDD areas of the pixel transistors.

Abstract: Techniques for promoting conductivity in a substrate for a pixel array. In an embodiment, an isolation region and a dopant well are disposed within an epitaxial layer adjoining the substrate, where a portion of the dopant well is between the substrate and a portion of the isolation well. In another embodiment, a contact is further disposed within the epitaxial layer, where a portion of the isolation region surrounds a portion of the contact.

Abstract: A method of fabricating a backside illuminated imaging sensor that includes a device layer, a metal stack, and an opening is disclosed. The device layer has an imaging array formed in a front side of the device layer, where the imaging array is adapted to receive light from a back side of the device layer. The metal stack is coupled to the front side of the device layer and includes at least one metal interconnect layer having a metal pad. The opening extends from the back side of the device layer to the metal pad to expose the metal pad for wire bonding. The method includes depositing a film on the back side of the device layer and within the opening, then etching the film to form a frame within the opening to structurally reinforce the metal pad.

Abstract: An image sensor includes a pixel array, a bit line, supplemental capacitance node line, and a supplemental capacitance circuit. The pixel array includes a plurality of pixel cells each including a floating diffusion (“FD”) node and a photosensitive element coupled to selectively transfer image charge to the FD node. The bit line is coupled to selectively conduct image data output from a first group of the pixel cells. The supplemental capacitance node line is coupled to the FD node of a second group of the pixel cells to selectively couple a supplemental capacitance to the FD nodes of the second group in response to a control signal. In various embodiments, the first and second group of pixel cells may be the same group or a different group of the pixel cells and may add a capacitive boost feature or a multi conversion gain feature.

Abstract: Embodiments of a process for forming a photodetector region in a CMOS pixel by dopant implantation, the process comprising masking a photodetector area of a surface of a substrate for formation of the photodetector region, positioning the substrate at a plurality of twist angles, and at each of the plurality of twist angles, directing dopants at the photodetector area at a selected tilt angle. Embodiments of a CMOS pixel comprising a photodetector region formed in a substrate, the photodetector region comprising overlapping first and second dopant implants, wherein the overlap region has a different dopant concentration than the non-overlapping parts of the first and second implants, a floating diffusion formed in the substrate, and a transfer gate formed on the substrate between the photodetector and the transfer gate. Other embodiments are disclosed and claimed.

Abstract: A technique for fabricating an image sensor including a pixel circuitry region and a peripheral circuitry region includes fabricating front side components on a front side of the image sensor. A dopant layer is implanted on a backside of the image sensor. A anti-reflection layer is formed on the backside and covers a first portion of the dopant layer under the pixel circuitry region while exposing a second portion of the dopant layer under the peripheral circuitry region. The first portion of the dopant layer is laser annealed from the backside of the image sensor through the anti-reflection layer. The anti-reflection layer increases a temperature of the first portion of the dopant layer during the laser annealing.

Abstract: An image sensor includes a device wafer substrate of a device wafer, a device layer of the device wafer, and optionally a heat control structure and/or a heat sink. The device layer is disposed on a frontside of the device wafer substrate and includes a plurality of photosensitive elements disposed within a pixel array region and peripheral circuitry disposed within a peripheral circuits region. The photosensitive elements are sensitive to light incident on a backside of the device wafer substrate. The heat control structure is disposed within the device wafer substrate and thermally isolates the pixel array region from the peripheral circuits region to reduce heat transfer between the peripheral circuits region and the pixel array region. The heat sink conducts heat away from the device layer.

Abstract: Embodiments of a pixel including a photosensitive region formed in a surface of a substrate and an overflow drain formed in the surface of the substrate at a distance from the photosensitive area, an electrical bias of the overflow drain being variable and controllable. Embodiments of a pixel including a photosensitive region formed in a surface of a substrate, a source-follower transistor coupled to the photosensitive region, the source-follower transistor including a drain, and a doped bridge coupling the photosensitive region to the drain of the source-follower transistor.

Abstract: Embodiments of the present invention are directed to an image sensor having pixel transistors and peripheral transistors disposed in a silicon substrate. For some embodiments, a protective coating is disposed on the peripheral transistors and doped silicon is epitaxially grown on the substrate to form lightly-doped drain (LDD) areas for the pixel transistors. The protective oxide may be used to prevent epitaxial growth of silicon on the peripheral transistors during formation of the LDD areas of the pixel transistors.