Abstract: A CMOS image sensor and method of fabrication wherein the sensor includes Copper (Cu) metallization levels allowing for incorporation of a thinner interlevel dielectric stack to result in a pixel array exhibiting increased light sensitivity. The CMOS image sensor includes structures having a minimum thickness of barrier layer metal that traverses the optical path of each pixel in the sensor array or, that have portions of barrier layer metal selectively removed from the optical paths of each pixel, thereby minimizing reflectance. That is, by implementing various block or single mask methodologies, portions of the barrier layer metal are completely removed at locations of the optical path for each pixel in the array. In a further embodiment, the barrier metal layer may be formed atop the Cu metallization by a self-aligned deposition.

Abstract: Enhanced efficiency solar cells and methods of manufacture of such cells are described herein. In an illustrative example, the solar cell includes at least one or more collector lens bars each of which extend on sides of front contacts and positioned over a respective active area of one or more active areas in such as position as to guide light onto the one or more active areas. A protective layer covers the at least one or more collector lens bars.

Abstract: Stitched integrated circuit (IC) chip layout design structures are disclosed. In one embodiment, a design structure embodied in a machine readable medium used in a design process includes: an integrated circuit (IC) chip layout exceeding a size of a photolithography tool field, the IC chip layout including: a plurality of stitched regions including at least one redundant stitched region or at least one unique stitched region; and for each stitched region: a boundary identification identifying a boundary of the stitched region at which stitching occurs.

Abstract: Stitched integrated circuit (IC) chip layout methods, systems and program products are disclosed. In one embodiment, a method includes obtaining from a first entity a circuit design for an IC chip layout that exceeds a size of a photolithography tool field at a second entity, wherein the IC chip layout includes for at least one stitched region of a plurality of stitched regions: a boundary identification identifying a boundary of the at least one stitched region at which stitching occurs and a type indicator indicating whether the at least one stitched region is one of: redundant and unique; dissecting the IC chip layout into stitched regions indicated as unique or redundant at the second entity; and generating a photolithographic reticle at the second entity based on the plurality of stitched regions, the photolithographic reticle having a size that fits within the size of the photolithographic tool field at the second entity.

Abstract: A method for manufacturing a stitched space in a semiconductor circuit implements a photolithographic process for printing one or more image fields on a wafer surface, each image field corresponding to a portion of a circuit or device and including a space that is to be stitched in adjacent image fields. The space to be stitched that is produced from an image field is overlapped onto the space to be stitched produced from the adjacent image field, however, the overlapped space from the adjacent image fields is intentionally misaligned. The stitched space is then subject to the double light exposure dose to print the stitched space, with the result that an overlay tolerance of the stitched space is improved.

Abstract: Methods for real-time contamination, environmental, or physical monitoring of a photomask. An attribute of a photomask is monitored using a sensor of an electronics package attached to the photomask. The methods further include generating one or more sensor signals relating to the monitored attribute with the sensor and transmitting the one or more sensor signals from the electronics package to a control system.

Abstract: Systems for real-time contamination, environmental, or physical monitoring of a photomask. The system includes an electronics package physically mounted to the photomask and a processing device in communication with the electronics package. The electronics package includes a sensor configured to monitor the attribute and generate sensor data. The processing device is configured to analyze the sensor data communicated from the electronics package to the processing device.

Abstract: A CMOS image sensor array and method of fabrication wherein the sensor includes Copper (Cu) metallization levels allowing for incorporation of a thinner interlevel dielectric stack with improved thickness uniformity to result in a pixel array exhibiting increased light sensitivity. In the sensor array, each Cu metallization level includes a Cu metal wire structure formed at locations between each array pixel and, a barrier material layer is formed on top each Cu metal wire structure that traverses the pixel optical path. By implementing a single mask or self-aligned mask methodology, a single etch is conducted to completely remove the interlevel dielectric and barrier layers that traverse the optical path. The etched opening is then refilled with dielectric material.

Abstract: A plurality of image sensor structures and a plurality of methods for fabricating the plurality of image sensor structures provide for inhibited cracking and delamination of a lens capping layer with respect to a planarizing layer within the plurality of image sensor structures. Particular image sensor structures and related methods include at least one dummy lens layer of different dimensions than active lens layer located over a circuitry portion of a substrate within the particular image sensor structures. Additional particular image sensor structures include at least one of an aperture within the planarizing layer and a sloped endwall of the planarizing layer located over a circuitry portion within the particular image sensor structures.

Abstract: Stitched circuitry region boundary identification for a stitched IC chip layout is presented along with a related IC chip and design structure. One method includes obtaining a circuit design for an integrated circuit (IC) chip layout that exceeds a size of a photolithography tool field, wherein the IC chip layout includes a stitched circuitry region; and modifying the IC chip layout to include a boundary identification identifying a boundary of the stitched circuitry region at which stitching occurs, wherein the boundary identification takes the form of a negative space in the IC chip layout. One IC chip may include a plurality of stitched circuitry regions; and a boundary identification identifying a boundary between a pair of the stitched circuitry regions, wherein the boundary identification takes the form of a negative space in a layer of the IC chip.

Abstract: Stitched circuitry region boundary identification for a stitched IC chip layout is presented along with a related IC chip and design structure. One method includes obtaining a circuit design for an integrated circuit (IC) chip layout that exceeds a size of a photolithography tool field, wherein the IC chip layout includes a stitched circuitry region; and modifying the IC chip layout to include a boundary identification identifying a boundary of the stitched circuitry region at which stitching occurs, wherein the boundary identification takes the form of a negative space in the IC chip layout. One IC chip may include a plurality of stitched circuitry regions; and a boundary identification identifying a boundary between a pair of the stitched circuitry regions, wherein the boundary identification takes the form of a negative space in a layer of the IC chip.

Abstract: An apparatus for real-time contamination, environmental, or physical monitoring of a photomask. The apparatus includes a photomask having a patterned region configured to correspond to features of an integrated circuit and a sensor physically coupled with the photomask. The sensor is configured to monitor an attribute related to the photomask. Attributes monitored by the sensor may include chemical contamination, temperature changes, humidity changes, acceleration, shock, vibration, optical flux through the photomask, electrostatic discharge environment of the photomask, particulates, and pressure.

Abstract: A flat-top convex-bottom lower lens is formed by first applying a positive tone photoresist over a silicon oxide layer and an optional metallic barrier layer thereupon in a back-end-of-line (BEOL) metallization structure. The positive tone photoresist is exposed under defocused illumination conditions and/or employing a half-tone mask so that a cross-sectional profile of the positive tone photoresist after exposure contains a continuous and smooth concave profile, which is transferred into the underlying silicon oxide layer to form a concave cavity therein. After removing the photoresist, the cavity is filled with a high refractive index material such as silicon nitride, and planarized to form a flat-top convex-bottom lower lens. Various aluminum metal structures, a color filter, and a convex-top flat-bottom upper lens are thereafter formed so that the upper lens and the lower lens constitute a composite lens system.

Abstract: An interconnect layout, an image sensor including the interconnect layout and a method for fabricating the image sensor each use a first electrically active physical interconnect layout pattern within an active pixel region and a second electrically active physical interconnect layout pattern spatially different than the first electrically active physical interconnect layout pattern within a dark pixel region. The second electrically active physical interconnect layout pattern includes at least one electrically active interconnect layer interposed between a light shield layer and a photosensor region aligned therebeneath, thus generally providing a higher wiring density. The higher wiring density within the second layout pattern provides that that the image sensor may be fabricated with enhanced manufacturing efficiency and a reduction of metallization levels.

Abstract: An interconnect layout, an image sensor including the interconnect layout and a method for fabricating the image sensor each use a first electrically active physical interconnect layout pattern within an active pixel region and a second electrically active physical interconnect layout pattern spatially different than the first electrically active physical interconnect layout pattern within a dark pixel region. The second electrically active physical interconnect layout pattern includes at least one electrically active interconnect layer interposed between a light shield layer and a photosensor region aligned therebeneath, thus generally providing a higher wiring density. The higher wiring density within the second layout pattern provides that that the image sensor may be fabricated with enhanced manufacturing efficiency and a reduction of metallization levels.

Abstract: An imaging system for use in a digital camera or cell phone utilizes one chip for logic and one chip for image processing. The chips are interconnected using around-the-edge or through via conductors extending from bond pads on the active surface of the imaging chip to backside metallurgy on the imaging chip. The backside metallurgy of the imaging chip is connected to metallurgy on the active surface of the logic chip using an array of solder bumps in BGA fashion. The interconnection arrangement provides a CSP which matches the space constraints of a cell phone, for example. The arrangement also utilizes minimal wire lengths for reduced noise. Connection of the CSP to a carrier package may be either by conductive through vias or wire bonding. The CSP is such that the imaging chip may readily be mounted across an aperture in the wall of a cell phone, for example, so as to expose the light sensitive pixels on the active surface of said imaging chip to light.

Abstract: An imaging system for use in a digital camera or cell phone utilizes one chip for logic and one chip for image processing. The chips are interconnected using around-the-edge or through via conductors extending from bond pads on the active surface of the imaging chip to backside metallurgy on the imaging chip. The backside metallurgy of the imaging chip is connected to metallurgy on the active surface of the logic chip using an array of solder bumps in BGA fashion. The interconnection arrangement provides a CSP which matches the space constraints of a cell phone, for example. The arrangement also utilizes minimal wire lengths for reduced noise. Connection of the CSP to a carrier package may be either by conductive through vias or wire bonding. The CSP is such that the imaging chip may readily be mounted across an aperture in the wall of a cell phone, for example, so as to expose the light sensitive pixels on the active surface of said imaging chip to light.

Abstract: A novel pixel sensor structure formed on a substrate of a first conductivity type includes a photosensitive device of a second conductivity type and a surface pinning layer of the first conductivity type. A trench isolation structure is formed adjacent to the photosensitive device pinning layer. The trench isolation structure includes a dopant region comprising material of the first conductivity type selectively formed along a sidewall of the isolation structure that is adapted to electrically couple the surface pinning layer to the underlying substrate. The corresponding method for forming the dopant region selectively formed along the sidewall of the isolation structure comprises an out-diffusion process whereby dopant materials present in a doped material layer formed along selected portions in the trench are driven into the underlying substrate during an anneal.

Abstract: A method for manufacturing a stitched space in a semiconductor circuit implements a photolithographic process for printing one or more image fields on a wafer surface, each image field corresponding to a portion of a circuit or device and including a space that is to be stitched in adjacent image fields. The space to be stitched that is produced from an image field is overlapped onto the space to be stitched produced from the adjacent image field, however, the overlapped space from the adjacent image fields is intentionally misaligned. The stitched space is then subject to the double light exposure dose to print the stitched space, with the result that an overlay tolerance of the stitched space is improved.

Abstract: Stitched integrated circuit (IC) chip layout methods, systems and program products are disclosed. In one embodiment, a method includes obtaining from a first entity a circuit design for an IC chip layout that exceeds a size of a photolithography tool field at a second entity, wherein the IC chip layout includes for at least one stitched region of a plurality of stitched regions: a boundary identification identifying a boundary of the at least one stitched region at which stitching occurs and a type indicator indicating whether the at least one stitched region is one of: redundant and unique; dissecting the IC chip layout into stitched regions indicated as unique or redundant at the second entity; and generating a photolithographic reticle at the second entity based on the plurality of stitched regions, the photolithographic reticle having a size that fits within the size of the photolithographic tool field at the second entity.