Abstract: Methods for improving hybrid bond yield for semiconductor wafers forming 3DIC devices includes first and second wafers having dummy and main metal deposited and patterned during BEOL processing. Metal of the dummy metal pattern occupies from about 40% to about 90% of the surface area of any given dummy metal pattern region. High dummy metal surface coverage, in conjunction with utilization of slotted conductive pads, allows for improved planarization of wafer surfaces presented for hybrid bonding. Planarized wafers exhibit minimum topographic differentials corresponding to step height differences of less than about 400 ?. Planarized first and second wafers are aligned and subsequently hybrid bonded with application of heat and pressure; dielectric-to-dielectric, RDL-to-RDL. Lithography controls to realize WEE from about 0.5 mm to about 1.5 mm may be employed to promote topographic uniformity at wafer edges.

Abstract: Various structures of image sensors are disclosed, as well as methods of forming the image sensors. According to an embodiment, a structure comprises a substrate comprising photo diodes, an oxide layer on the substrate, recesses in the oxide layer and corresponding to the photo diodes, a reflective guide material on a sidewall of each of the recesses, and color filters each being disposed in a respective one of the recesses. The oxide layer and the reflective guide material form a grid among the color filters, and at least a portion of the oxide layer and a portion of the reflective guide material are disposed between neighboring color filters.

Abstract: A device includes a semiconductor substrate, a plurality of micro-lenses disposed on the substrate, each micro-lens being configured to direct light radiation to a layer beneath the plurality of micro-lenses. The device further includes a transparent layer positioned between the plurality of micro-lenses and the substrate, the transparent layer comprising a structure that is configured to block light radiation that is traveling towards a region between adjacent micro-lenses, wherein the structure and the transparent material are coplanar at respective top surfaces and bottom surfaces thereof.

Abstract: The present disclosure relates to an integrated circuit, and an associated method of formation. In some embodiments, the integrated circuit comprises a deep trench grid disposed at a back side of a substrate. A passivation layer lines the deep trench grid within the substrate. The passivation layer includes a first high-k dielectric layer and a second high-k dielectric layer disposed over the first high-k dielectric layer. A first dielectric layer is disposed over the passivation layer, lining the deep trench grid and extending over an upper surface of the substrate. A second dielectric layer is disposed over the first dielectric layer and enclosing remaining spaces of the deep trench grid to form air-gaps at lower portions of the deep trench grid. The air-gaps are sealed by the first dielectric layer or the second dielectric layer below the upper surface of the substrate.

Abstract: A semiconductor device includes a substrate, light sensing devices, at least one infrared radiation sensing device, a transparent insulating layer, an infrared radiation cut layer, a color filter layer and an infrared radiation color filter layer. The light sensing devices and the at least one infrared radiation sensing device are disposed in the substrate and are adjacent to each other. The transparent insulating layer is disposed on the substrate overlying the light sensing devices and the at least one infrared radiation sensing device. The infrared radiation cut layer is disposed on the transparent insulating layer overlying the light sensing devices for filtering out infrared radiation and/or near infrared radiation. The color filter layer is disposed on the infrared radiation cut layer. The infrared radiation color filter layer is disposed on the transparent insulating layer overlying the at least one infrared radiation sensing device.

Abstract: In some embodiments, the present disclosure relates to a multi-dimensional integrated chip having a redistribution structure vertically extending between integrated chip die at a location laterally offset from a bond pad. The integrated chip structure has a first die and a second die. The first die has a first plurality of interconnect layers arranged within a first dielectric structure disposed on a first substrate. The second die has a second plurality of interconnect layers arranged within a second dielectric structure disposed between the first dielectric structure and a second substrate. A bond pad is disposed within a recess extending through the second substrate. A redistribution structure electrically couples the first die to the second die at a position that is laterally offset from the bond pad.

Abstract: The present disclosure relates to a semiconductor image sensor device. In some embodiments, the semiconductor image sensor device includes a semiconductor substrate having a first surface configured to receive incident radiation. A plurality of sensor elements are arranged within the semiconductor substrate. A first charged layer is arranged on an entirety of a second surface of the semiconductor substrate facing an opposite direction as the first surface. The second surface is between the first charged layer and the first surface of the semiconductor substrate.

Abstract: A method includes forming a photo resist over a semiconductor substrate of a wafer, patterning the photo resist to form a first opening in the photo resist, and implanting the semiconductor substrate using the photo resist as an implantation mask. An implanted region is formed in the semiconductor substrate, wherein the implanted region is overlapped by the first opening. A coating layer is coated over the photo resist, wherein the coating layer includes a first portion in the first opening, and a second portion over the photo resist. A top surface of the first portion is lower than a top surface of the second portion. The coating layer, the photo resist, and the implanted region are etched to form a second opening in the implanted region.

Abstract: A backside illuminated (BSI) image sensor for biased backside deep trench isolation (BDTI) and/or biased backside shielding is provided. A photodetector is arranged in a semiconductor substrate, laterally adjacent to a peripheral opening in the semiconductor substrate. An interconnect structure is arranged under the semiconductor substrate. A pad structure is arranged in the peripheral opening, and protrudes through a lower surface of the peripheral opening to the interconnect structure. A conductive layer is electrically coupled to the pad structure, and extends laterally towards the photodetector from over the pad structure. A method for manufacturing the BSI image sensor is also provided.

Abstract: An integrated circuit (IC) using a copper-alloy based hybrid bond is provided. The IC comprises a pair of semiconductor structures vertically stacked upon one another. The pair of semiconductor structures comprise corresponding dielectric layers and corresponding metal features arranged in the dielectric layers. The metal features comprise a copper alloy having copper and a secondary metal. The IC further comprises a hybrid bond arranged at an interface between the semiconductor structures. The hybrid bond comprises a first bond bonding the dielectric layers together and a second bond bonding the metal features together. The second bond comprises voids arranged between copper grains of the metal features and filled by the secondary metal. A method for bonding a pair of semiconductor structures together using the copper-alloy based hybrid bond is also provided.

Abstract: The present disclosure relates to a BSI image sensor with improved DTI structures, and an associated method of formation. In some embodiments, the BSI image sensor comprises a plurality of image sensing elements disposed within a substrate corresponding to a plurality of pixel regions. A deep trench isolation (DTI) grid is disposed between adjacent image sensing elements and extending from an upper surface of the substrate to positions within the substrate. The DTI grid comprises air-gaps disposed under the upper surface of the substrate, the air-gaps having lower portions surrounded by a first dielectric layer and some upper portions sealed by a second dielectric layer.

Abstract: In some embodiments, the present disclosure relates to an integrated chip (IC) structure having a conductive blocking structure configured prevent radiation produced by a device within a first die from affecting an image sensing element within a second die. The IC structure has a first IC die with one or more semiconductor devices and a second IC die with an array of image sensing elements. A hybrid bonding interface region is arranged between the first and second IC die. A conductive bonding structure is arranged within the hybrid bonding interface region and is configured to electrically couple the first IC die to the second IC die. A conductive blocking structure is arranged within the hybrid bonding interface region and extends laterally between the one or more semiconductor devices and the array of image sensing elements.

Abstract: Presented herein is a device including an image sensor having a plurality of pixels disposed in a substrate and configured to sense light through a back side of the substrate and an RDL disposed on a front side of the substrate and having a plurality of conductive elements disposed in one or more dielectric layers. A sensor shield is disposed over the back side of the substrate and extending over the image sensor. At least one via contacts the sensor shield and extends from the sensor shield through at least a portion of the RDL and contacts at least one of the plurality of conductive elements.

Abstract: A method of fabrication of alignment marks for a non-STI CMOS image sensor is introduced. In some embodiments, zero layer alignment marks and active are alignment marks may be simultaneously formed on a wafer. A substrate of the wafer may be patterned to form one or more recesses in the substrate. The recesses may be filled with a dielectric material using, for example, a field oxidation method and/or suitable deposition methods. Structures formed by the above process may correspond to elements of the zero layer alignment marks and/or to elements the active area alignment marks.

Abstract: A method includes forming a plurality of pixels formed on a front surface of a semiconductor substrate, forming an array of color filters over the plurality of pixels, each color filter being adapted for allowing a wavelength of light radiation to reach at least one of the plurality of pixels, forming a plurality of micro-lenses over the array of color filters, and forming a second layer between the pixels and the color filters. The second layer further includes a structure adapted for blocking light radiation that is traveling towards a region between adjacent micro-lens, further wherein the plurality of micro-lenses are in contact with the array of color filters, and wherein the structure and the transparent material are coplanar at respective top surfaces thereof, and further wherein the structure directly contacts a bottom surface of at least one of the color filters.

Abstract: A semiconductor device includes a substrate, light sensing devices, at least one infrared radiation sensing device, a transparent insulating layer, an infrared radiation cut layer, a color filter layer and an infrared radiation color filter layer. The light sensing devices and the at least one infrared radiation sensing device are disposed in the substrate and are adjacent to each other. The transparent insulating layer is disposed on the substrate overlying the light sensing devices and the at least one infrared radiation sensing device. The infrared radiation cut layer is disposed on the transparent insulating layer overlying the light sensing devices for filtering out infrared radiation and/or near infrared radiation. The color filter layer is disposed on the infrared radiation cut layer. The infrared radiation color filter layer is disposed on the transparent insulating layer overlying the at least one infrared radiation sensing device.

Abstract: The present disclosure relates to a multi-dimensional integrated chip having a redistribution layer vertically extending between integrated chip die, which is laterally offset from a back-side bond pad. The multi-dimensional integrated chip has a first integrated chip die with a first plurality of metal interconnect layers disposed within a first inter-level dielectric layer arranged onto a front-side of a first semiconductor substrate. The multi-dimensional integrated chip also has a second integrated chip die with a second plurality of metal interconnect layers disposed within a second inter-level dielectric layer abutting the first ILD layer. A bond pad is disposed within a recess extending through the second semiconductor substrate. A redistribution layer vertically extends between the first plurality of metal interconnect layers and the second plurality of metal interconnect layers at a position that is laterally offset from the bond pad.

Abstract: Various structures of image sensors are disclosed, as well as methods of forming the image sensors. According to an embodiment, a structure comprises a substrate comprising photo diodes, an oxide layer on the substrate, recesses in the oxide layer and corresponding to the photo diodes, a reflective guide material on a sidewall of each of the recesses, and color filters each being disposed in a respective one of the recesses. The oxide layer and the reflective guide material form a grid among the color filters, and at least a portion of the oxide layer and a portion of the reflective guide material are disposed between neighboring color filters.

Abstract: Some embodiments of the present disclosure relate to an integrated chip having a via support structure underlying a bond pad. The integrated chip has an image sensing element arranged within a substrate. A bond pad region extends through the substrate, at a location laterally offset from the image sensing element, to a first metal interconnect wire arranged within a dielectric structure along a front-side of the substrate. A bond pad is arranged within the bond pad region and contacts the first metal interconnect wire. A via support structure is arranged within the dielectric structure and has one or more vias that are separated from the bond pad by the first metal interconnect wire. One or more additional vias are arranged within the dielectric structure at a location laterally offset from the bond pad region. The one or more vias have larger sizes than the one or more additional vias.

Abstract: The present disclosure relates to a stacked SPAD image sensor with a CMOS Chip and an imaging chip bonded together, to improve the fill factor of the SPAD image sensor, and an associated method of formation. In some embodiments, the imaging chip has a plurality of SPAD cells disposed within a second substrate. The CMOS Chip has a first interconnect structure disposed over a first substrate. The imaging chip has a second interconnect structure disposed between the second substrate and the first interconnect structure. The CMOS Chip and the imaging chip are bonded together through along an interface disposed between the first interconnect structure and the second interconnect structure.