Abstract: A device including a gate structure formed over a semiconductor substrate, the gate structure having extensions, a device isolation structure formed into the semiconductor substrate adjacent the gate structure, wherein the extensions are over a portion of the device isolation structure, and source/drain regions on both sides of the gate structure, the source/drain regions being formed in a gap in the device isolation structure and being partially enclosed by the extensions of the gate structure.

Abstract: A device includes a device isolation region formed into a semiconductor substrate, the device isolation region having gaps for photo-sensitive devices, a dummy gate structure formed over the substrate, the dummy gate structure comprising at least one structure that partially surrounds a doped pickup region formed into the device isolation region, and a via connected to the doped pickup region.

Abstract: A method includes forming a first implantation mask comprising a first opening, implanting a first portion of a semiconductor substrate through the first opening to form a first doped region, forming a second implantation mask comprising a second opening, and implanting a second portion of the semiconductor substrate to form a second doped region. The first portion of the semiconductor substrate is encircled by the second portion of the semiconductor substrate. A surface layer of the semiconductor substrate is implanted to form a third doped region of an opposite conductivity type than the first and the second doped regions. The third doped region forms a diode with the first and the second doped regions.

Abstract: The present disclosure provides for multiple gate dielectric semiconductor structures and methods of forming such structures. In one embodiment, a method of forming a semiconductor structure includes providing a substrate including a pixel array region, an input/output (I/O) region, and a core region. The method further includes forming a first gate dielectric layer over the pixel array region, forming a second gate dielectric layer over the I/O region, and forming a third gate dielectric layer over the core region, wherein the first gate dielectric layer, the second gate dielectric layer, and the third gate dielectric layer are each formed to be comprised of a different material and to have a different thickness.

Abstract: A semiconductor device including first and second isolation regions supported by a substrate, a first array well supported by the first isolation region, the first array well having a first field implant layer embedded therein, the first field implant layer surrounding a first shallow trench isolation region, a second array well supported by the second isolation region, the second array well supporting a doped region and a drain and having a second field implant layer embedded therein, the second field implant layer surrounding a second shallow trench isolation region, a stack of photodiodes disposed in the substrate between the first and second isolation regions, and a gate oxide formed over an uppermost photodiode of the stack of the photodiodes, the gate oxide and a silicon of the uppermost photodiode forming an interface, a nitrogen concentration at the interface offset from a peak nitrogen concentration.

Abstract: A device includes a diode, which includes a first, a second, and a third doped region in a semiconductor substrate. The first doped region is of a first conductivity type, and has a first impurity concentration. The second doped region is of the first conductivity type, and has a second impurity concentration lower than the first impurity concentration. The second doped region encircles the first doped region. The third doped region is of a second conductivity type opposite the first conductivity type, wherein the third doped region overlaps a portion of the first doped region and a portion of the second doped region.

Abstract: An image sensor the image sensor comprising an absorption layer disposed on a silicon substrate, the absorption layer having at least one of SiGe or Ge, and an antireflection layer disposed directly thereon.

Abstract: The present disclosure provides for multiple gate dielectric semiconductor structures and methods of forming such structures. In one embodiment, a method of forming a semiconductor structure includes providing a substrate including a pixel array region, an input/output (I/O) region, and a core region. The method further includes forming a first gate dielectric layer over the pixel array region, forming a second gate dielectric layer over the I/O region, and forming a third gate dielectric layer over the core region, wherein the first gate dielectric layer, the second gate dielectric layer, and the third gate dielectric layer are each formed to be comprised of a different material and to have a different thickness.

Abstract: Provided is an image sensor device. The image sensor device includes having a front side, a back side, and a sidewall connecting the front and back sides. The image sensor device includes a plurality of radiation-sensing regions disposed in the substrate. Each of the radiation-sensing regions is operable to sense radiation projected toward the radiation-sensing region through the back side. The image sensor device includes an interconnect structure that is coupled to the front side of the substrate. The interconnect structure includes a plurality of interconnect layers and extends beyond the sidewall of the substrate. The image sensor device includes a bonding pad that is spaced apart from the sidewall of the substrate. The bonding pad is electrically coupled to one of the interconnect layers of the interconnect structure.

Abstract: An image sensor the image sensor comprising an absorption layer disposed on a silicon substrate, the absorption layer having at least one of SiGe or Ge, and an antireflection layer disposed directly thereon.

Abstract: A memory cell comprising a capacitor having a dielectric layer interposing first and second vertically disposed electrodes, an insulating lining located over the capacitor, and a transistor gate extension passing over the capacitor. A spacer isolates an end of one of the capacitor electrodes from the transistor gate extension. In one embodiment, the spacer includes a first non-planar profile configured to engage a second non-planar profile comprising ends of the one of the capacitor electrodes and the insulating lining.

Abstract: A method for forming a metal-interlayer-metal (MIM) device in an embedded memory device, including semiconductor devices thereof. An MIM device can be formed upon a semiconductor substrate utilizing no more than one additional photo mask layer prior to the implementation of a back-end-of-line (BEOL) semiconductor fabrication operation, such that the MIM device can be configured as a low temperature MIM device that is fully compatible with logical semiconductor devices, thereby reducing associated manufacturing costs. The MIM device may be configured as an MIM capacitor for logic-based embedded DRAM devices, resulting in a high capacitance performed via an effective area extension of DRAM cell capacitors. Additonally, a low-temperature MIM capacitor thereof may be readily integrated for both Cu (Copper) and AlCu (Aluminum Copper) BEOL fabrication processes.

Abstract: A method and system for manufacturing an MIM capacitor for utilization with a logic-based embedded DRAM device. At least one transistor, an interlayer dielectric, at least one contact and at least one metal one layer are generally formed on a substrate during a front end manufacturing operation of the capacitor on the substrate. An inter-metal dielectric layer is deposited upon the substrate, followed thereafter by a chemical mechanical polishing operation. Additionally, a lithographic operation is performed upon the substrate. Also, at least one dielectric deposition layer is generally on the substrate, followed thereafter by a chemical mechanical polishing operation and a stop on an oxide layer formed on the substrate. At least one metal two layer may then be formed on substrate and associated layers thereof, thereby resulting in the formation of a capacitor fully compatible with logic-based devices and processes thereof.

Abstract: A method and system for manufacturing an MIM capacitor for utilization with a logic-based embedded DRAM device. At least one transistor, an interlayer dielectric, at least one contact and at least one metal one layer are generally formed on a substrate during a front end manufacturing operation of the capacitor on the substrate. An inter-metal dielectric layer is deposited upon the substrate, followed thereafter by a chemical mechanical polishing operation. Additionally, a lithographic operation is performed upon the substrate. Also, at least one dielectric deposition layer is generally on the substrate, followed thereafter by a chemical mechanical polishing operation and a stop on an oxide layer formed on the substrate. At least one metal two layer may then be formed on substrate and associated layers thereof, thereby resulting in the formation of a capacitor fully compatible with logic-based devices and processes thereof.

Abstract: A method for forming a metal-interlayer-metal (MIM) device in an embedded memory device, including semiconductor devices thereof. An MIM device can be formed upon a semiconductor substrate utilizing no more than one additional photo mask layer prior to the implementation of a back-end-of-line (BEOL) semiconductor fabrication operation, such that the MIM device can be configured as a low temperature MIM device that is fully compatible with logical semiconductor devices, thereby reducing associated manufacturing costs. The MIM device may be configured as an MIM capacitor for logic-based embedded DRAM devices, resulting in a high capacitance performed via an effective area extension of DRAM cell capacitors. Additonally, a low-temperature MIM capacitor thereof may be readily integrated for both Cu (Copper) and AlCu (Aluminum Copper) BEOL fabrication processes.

Abstract: A method is described for making capacitor-under-bit line (CUB) DRAM cells with improved overlay margins between bit lines and capacitor top electrodes. After forming FETs for the memory cells, an interpolysilicon oxide (IPO) layer is deposited, and first and second plug contacts are formed in the IPO to the FET source/drain areas for capacitors and bit line contacts, respectively. A capacitor node oxide is deposited, and first openings are etched in which crown capacitor bottom electrodes are formed. After etching back the node oxide a thin interelectrode dielectric layer is formed and a conformal conducting layer is deposited to form capacitor top electrodes. A photoresist mask is used to etch openings in the conducting layer over the second plug contacts, and an isotropic etch is used to recess the openings under the mask to increase the spacing between the capacitor top electrodes and the bit line contacts to improve the overlay margin.

Abstract: A process for integrating the formation of a salicide layer on DRAM word line structures, and on a bit line contact structure, has been developed. The process features selective etch back of the insulator layers embedding the tapered shaped bit line contact, and the tapered shape capacitor structures, exposing top surface portions of polysilicon word line structures. The selective etch back procedure also results in formation of insulator spacers on the sides of the tapered bit line contact, and capacitor structures, allowing a subsequent salicide procedure to form metal suicide layers only on the exposed top surfaces of the DRAM word line, bit line contact, and capacitor structures.