Abstract: A semiconductor image sensor device includes a semiconductor substrate, a radiation-sensing region, and a first isolation structure. The radiation-sensing region is in the semiconductor substrate. The first isolation structure is in the semiconductor substrate and adjacent to the radiation-sensing region. The first isolation structure includes a bottom isolation portion in the semiconductor substrate, an upper isolation portion in the semiconductor substrate, and a diffusion barrier layer surrounding a sidewall of the upper isolation portion.

Abstract: Some embodiments relate to an image sensor. The image sensor includes a semiconductor substrate including a pixel region and a peripheral region. A backside isolation structure extends into a backside of the semiconductor substrate and laterally surrounds the pixel region. The backside isolation structure includes a metal core, and a dielectric liner separates the metal core from the semiconductor substrate. A conductive feature is disposed over a front side of the semiconductor substrate. A through substrate via extends from the backside of the semiconductor substrate through the peripheral region to contact the conductive feature. The through substrate via is laterally offset from the backside isolation structure. A conductive bridge is disposed beneath the backside of the semiconductor substrate and electrically couples the metal core of the backside isolation structure to the through substrate via.

Abstract: An image sensor includes a pixel and an isolation structure. The pixel includes a photosensitive region and a circuitry region next to the photosensitive region. The isolation structure is located over the pixel, where the isolation structure includes a conductive grid and a dielectric structure covering a sidewall of the conductive grid, and the isolation structure includes an opening or recess overlapping the photosensitive region. The isolation structure surrounds a peripheral region of the photosensitive region.

Abstract: In some embodiments, the present disclosure relates to an integrated chip that includes a first image sensing element and a second image sensing element arranged over a substrate. A first micro-lens is arranged over the first image sensing element, and a second micro-lens is arranged over the second image sensing element. A composite deep trench isolation structure is arranged between the first and second image sensing elements. The composite deep trench isolation structure includes a lower portion arranged over the substrate and an upper portion arranged over the lower portion. The lower portion includes a first material, and the upper portion includes a second material that has a higher reflectivity than the first material.

Abstract: A method of fabricating a semiconductor device includes forming a first film having a first film stress type and a first film stress intensity over a substrate and forming a second film having a second film stress type and a second film stress intensity over the first film. The second film stress type is different than the first film stress type. The second film stress intensity is about same as the first film stress intensity. The second film compensates stress induced effect of non-flatness of the substrate by the first film.

Abstract: A semiconductor structure is disclosed. The semiconductor structure includes: a semiconductor substrate having a front surface and a back surface facing opposite to the front surface; a filling material extending from the front surface into the semiconductor substrate without penetrating through the semiconductor substrate, the filling material including an upper portion and a lower portion, the upper portion being in contact with the semiconductor substrate; and an epitaxial layer lined between the lower portion of the filling material and the semiconductor substrate. An associated manufacturing method is also disclosed.

Abstract: A method of fabricating a semiconductor device includes receiving a device substrate; forming an interconnect structure on a front side of the device substrate; and etching a recess into a backside of the device substrate until a portion of the interconnect structure is exposed. The recess has a recess depth and an edge of the recess is defined by a sidewall of the device substrate. A conductive bond pad is formed in the recess, and a first plurality of layers cover the conductive bond pad, extend along the sidewall of the device substrate, and cover the backside of the device substrate. The first plurality of layers collectively have a first total thickness that is less than the recess depth. A first chemical mechanical planarization is performed to remove portions of the first plurality of layers so remaining portions of the first plurality of layers cover the conductive bond pad.

Abstract: A device and method for fabricating the same is disclosed. For example, the device includes a sensor having a front side and a back side, a metal interconnect layer formed on the front side of the sensor, an anti-reflective coating formed on the back side of the sensor, a composite etch stop mask layer formed on the anti-reflective coating wherein the composite etch stop mask layer includes a hydrogen rich layer and a compressive high density layer, and a light filter formed on the composite etch stop mask layer.

Abstract: An isolation structure can be formed between adjacent and/or non-adjacent pixel regions (e.g., between diagonal or cross-road pixel regions), of an image sensor, to reduce and/or prevent optical crosstalk. The isolation structure may include a deep trench isolation (DTI) structure or another type of trench that is partially filled with a material such that an air gap is formed therein. The DTI structure having the air gap formed therein may reduce optical crosstalk between pixel regions. The reduced optical crosstalk may increase spatial resolution of the image sensor, may increase overall sensitivity of the image sensor, may decrease color mixing between pixel regions of the image sensor, and/or may decrease image noise after color correction of images captured using the image sensor.

Abstract: Metal-insulator-metal (MIM) capacitor, an integrated semiconductor device having a MIM capacitor and methods of making. The MIM capacitor includes a first metal layer, a second metal layer and a dielectric layer located between the second metal layer and the first metal layer. The first metal layer, the second metal layer and the dielectric layer may be formed in a comb structure, wherein the comb structure include a first tine structure and at least a second tine structure.

Abstract: The present disclosure, in some embodiments, relates to an integrated chip structure. The integrated chip structure includes a first substrate having an upper surface and a recessed surface extending in a closed loop around the upper surface. The recessed surface is vertically between the upper surface and a lower surface of the first substrate opposing the upper surface. A first plurality of interconnects are disposed within a first dielectric structure on the upper surface. A dielectric protection layer is over the recessed surface, along a sidewall of the first dielectric structure, and along a sidewall of the first substrate. The first substrate extends from directly below the dielectric protection layer to laterally outside of the dielectric protection layer.

Abstract: A plurality of radiation-sensing doped regions are formed in a substrate. A trench is formed in the substrate between the radiation-sensing doped regions. A SiOCN layer is filled in the trench by reacting Bis(tertiary-butylamino)silane (BTBAS) and a gas mixture comprising N2O, N2 and O2 through a plasma enhanced atomic layer deposition (PEALD) method, to form an isolation structure between the radiation-sensing doped regions.

Abstract: The present disclosure, in some embodiments, relates to a method of forming an integrated chip structure. The method may be performed by forming a plurality of interconnect layers within a first interconnect structure disposed over an upper surface of a first semiconductor substrate. An edge trimming process is performed to remove parts of the first interconnect structure and the first semiconductor substrate along a perimeter of the first semiconductor substrate. The edge trimming process results in the first semiconductor substrate having a recessed surface coupled to the upper surface by way of an interior sidewall disposed directly over the first semiconductor substrate. A dielectric protection layer is formed onto a sidewall of the first interconnect structure after performing the edge trimming process.

Abstract: In some embodiments, a method for bonding semiconductor wafers is provided. The method includes forming a first integrated circuit (IC) over a central region of a first semiconductor wafer. A first ring-shaped bonding support structure is formed over a ring-shaped peripheral region of the first semiconductor wafer, where the ring-shaped peripheral region of the first semiconductor wafer encircles the central region of the first semiconductor wafer. A second semiconductor wafer is bonded to the first semiconductor wafer, such that a second IC arranged on the second semiconductor wafer is electrically coupled to the first IC.

Abstract: The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes a photodetector arranged within a substrate. The substrate has surfaces defining one or more protrusions arranged along a first side of the substrate over the photodetector. One or more isolation structures are arranged within one or more trenches defined by sidewalls of the substrate arranged on opposing sides of the photodetector. The one or more trenches extend from the first side of the substrate to within the substrate. The one or more isolation structures respectively include a reflective medium configured to reflect electromagnetic radiation.

Abstract: A gas shower head includes a plate, a plurality of central holes disposed in a central region of the plate, and a plurality of peripheral holes disposed in a peripheral region of the plate. The central holes are configured to form a first portion of a material film, and the peripheral holes are configured to form a second portion of the material film. A hole density in the peripheral region is greater than a hole density in the central region. The first portion of the material film includes a first thickness corresponding to the hole density in central region, and the second portion of the material film includes a second thickness corresponding to the hole density in peripheral region and greater than the first thickness.

Abstract: The present disclosure, in some embodiments, relates to a method of forming an integrated chip structure. The method may be performed by forming a plurality of interconnect layers within a first interconnect structure disposed over an upper surface of a first semiconductor substrate. An edge trimming process is performed to remove parts of the first interconnect structure and the first semiconductor substrate along a perimeter of the first semiconductor substrate. The edge trimming process results in the first semiconductor substrate having a recessed surface coupled to the upper surface by way of an interior sidewall disposed directly over the first semiconductor substrate. A dielectric capping structure is formed onto a sidewall of the first interconnect structure after performing the edge trimming process.

Abstract: The present disclosure, in some embodiments, relates to a method of forming an integrated chip structure. The method may be performed by forming a plurality of interconnect layers within a first interconnect structure disposed over an upper surface of a first semiconductor substrate. An edge trimming process is performed to remove parts of the first interconnect structure and the first semiconductor substrate along a perimeter of the first semiconductor substrate. The edge trimming process results in the first semiconductor substrate having a recessed surface coupled to the upper surface by way of an interior sidewall disposed directly over the first semiconductor substrate. A dielectric protection layer is formed onto a sidewall of the first interconnect structure after performing the edge trimming process.

Abstract: The present disclosure, in some embodiments, relates to an image sensor integrated chip. The image sensor integrated chip includes an image sensing element arranged within a substrate. One or more isolation structures are arranged within one or more trenches disposed on opposing sides of the image sensing element. The one or more isolation structures extend from a first surface of the substrate to within the substrate. The one or more isolation structures respectively include a reflective element configured to reflect electromagnetic radiation.

Abstract: A device and method for fabricating the same is disclosed. For example, the device includes a sensor having a front side and a back side, a metal interconnect layer formed on the front side of the sensor, an anti-reflective coating formed on the back side of the sensor, a composite etch stop mask layer formed on the anti-reflective coating wherein the composite etch stop mask layer includes a hydrogen rich layer and a compressive high density layer, and a light filter formed on the composite etch stop mask layer.