Abstract: An image sensor includes a semiconductor substrate, a gate dielectric layer, a gate electrode, a protection oxide film, and a nitride hard mask. The gate dielectric layer is over the semiconductor substrate. The gate electrode is over the gate dielectric layer. An entirety of a first portion of the gate dielectric layer directly under the gate electrode is of uniform thickness. The protection oxide film is in contact with a top surface of the gate electrode. The gate dielectric layer extends beyond a sidewall of the protection oxide film. The nitride hard mask is in contact with a top surface of the protection oxide film.

Abstract: An image sensor with stress adjusting layers and a method of fabrication the image sensor are disclosed. The image sensor includes a substrate with a front side surface and a back side surface opposite to the front side surface, an anti-reflective coating (ARC) layer disposed on the back side surface of the substrate, a dielectric layer disposed on the ARC layer, a metal layer disposed on the dielectric layer, and a stress adjusting layer disposed on the metal layer. The stress adjusting layer includes a silicon-rich oxide layer. The concentration profiles of silicon and oxygen atoms in the stress adjusting layer are non-overlapping and different from each other. The image sensor further includes oxide grid structure disposed on the stress adjusting layer.

Abstract: A semiconductor arrangement is provided. The semiconductor arrangement includes a first component in a substrate. The semiconductor arrangement includes a gap fill layer. A first portion of the gap fill layer overlies the first component. The first portion of the gap fill layer has a tapered sidewall. A first portion of the substrate separates the first portion of the gap fill layer from the first component.

Abstract: A semiconductor structure includes a photodetector, which includes a substrate semiconductor layer having a doping of a first conductivity type, a second-conductivity-type photodiode layer that forms a p-n junction with the substrate semiconductor layer, a floating diffusion region that is laterally spaced from the second-conductivity-type photodiode layer, and a transfer gate electrode including a lower transfer gate electrode portion that is formed within the substrate semiconductor layer and located between the second-conductivity-type photodiode layer and the floating diffusion region. The transfer gate electrode may laterally surround the p-n junction, and may provide enhanced electron transmission efficiency from the p-n junction to the floating diffusion region. An array of photodetectors may be used to provide an image sensor.

Abstract: A semiconductor structure is provided. The semiconductor structure includes a first semiconductor device. The semiconductor structure includes a first semiconductor device and a second semiconductor device. The first semiconductor device includes a first oxide layer formed below the a first substrate, a first bonding layer formed below the first oxide layer, and a first bonding via formed through the first bonding layer and the first oxide layer. The second semiconductor device includes a second oxide layer formed over a second substrate, a second bonding layer formed over the second oxide layer, and a second bonding via formed through the second bonding layer and the second oxide layer. The semiconductor structure also includes a bonding structure between the first substrate and the second substrate, and the bonding structure includes the first bonding via bonded to the second bonding via.

Abstract: An image sensor device includes a substrate, photosensitive pixels, an interconnect structure, a dielectric layer, and a light blocking element. The photosensitive pixels are in the substrate. The interconnect structure is over a first side of the substrate. The dielectric layer is over a second side of the substrate opposite the first side of the substrate. The light blocking element has a first portion extending over a top surface of the dielectric layer and a second portion extending in the dielectric layer. The second portion of the light blocking element laterally surrounds the photosensitive pixels.

Abstract: Exemplary embodiments for redistribution layers of integrated circuit components are disclosed. The redistribution layers of integrated circuit components of the present disclosure include one or more arrays of conductive contacts that are configured and arranged to allow a bonding wave to displace air between the redistribution layers during bonding. This configuration and arrangement of the one or more arrays minimize discontinuities, such as pockets of air to provide an example, between the redistribution layers during the bonding.

Abstract: A method of detecting electromagnetic radiation includes illuminating a photodiode of a pixel sensor with electromagnetic radiation, using vertical gate structures of a transfer transistor to couple a cathode of the photodiode to an internal node of the pixel sensor, thereby generating an internal node voltage level, and generating an output voltage level of the pixel sensor based on the internal node voltage level.

Abstract: A semiconductor image sensor includes a substrate having a first side and a second side that is opposite the first side. An interconnect structure is disposed over the first side of the substrate. A plurality of radiation-sensing regions is located in the substrate. The radiation-sensing regions are configured to sense radiation that enters the substrate from the second side. A plurality of isolation structures are each disposed between two respective radiation-sensing regions. The isolation structures protrude out of the second side of the substrate.

Abstract: Photosensors may be formed on a front side of a semiconductor substrate. An optical refraction layer having a first refractive index may be formed on a backside of the semiconductor substrate. A grid structure including openings is formed over the optical refraction layer. A masking material layer is formed over the grid structure and the optical refraction layer. The masking material layer may be anisotropically etched using an anisotropic etch process that collaterally etches a material of the optical refraction layer and forms non-planar distal surface portions including random protrusions on physically exposed portions of the optical refraction layer. An optically transparent layer having a second refractive index that is different from the first refractive index may be formed on the non-planar distal surface portions of the optical refraction layer. A refractive interface refracts incident light in random directions, and improves quantum efficiency of the photo sensors.

Abstract: A pixel sensor may include a deep trench isolation (DTI) structure that extends the full height of a substrate in which a photodiode of the pixel sensor is included. Incident light entering the pixel sensor at a non-orthogonal angle is absorbed or reflected by the DTI structure along the full height of the substrate. In this way, the DTI structure may reduce, minimize, and/or prevent the incident light from traveling through the pixel sensor and into an adjacent pixel sensor along the full height of the substrate. This may increase the spatial resolution of an image sensor in which the DTI structure is included, may increase the overall sensitivity of the image sensor, may reduce and/or prevent color mixing between pixel sensors of the image sensor, and/or may decrease image noise after color correction.

Abstract: A front-side peripheral region of a first wafer may be edge-trimmed by performing a first pre-bonding edge-trimming process. A second wafer to be bonded with the first wafer is provided. Optionally, a front-side peripheral region of the second wafer may be edge-trimmed by performing a second pre-bonding edge-trimming process. A front surface of the first wafer is bonded to a front surface of a second wafer to form a bonded assembly. A backside of the first wafer is thinned by performing at least one wafer thinning process. The first wafer and a front-side peripheral region of the second wafer may be edge-trimmed by performing a post-bonding edge-trimming process. The bonded assembly may be subsequently diced into bonded semiconductor chips.

Abstract: A front-side peripheral region of a first wafer may be edge-trimmed by performing a first pre-bonding edge-trimming process. A second wafer to be bonded with the first wafer is provided. Optionally, a front-side peripheral region of the second wafer may be edge-trimmed by performing a second pre-bonding edge-trimming process. A front surface of the first wafer is bonded to a front surface of a second wafer to form a bonded assembly. A backside of the first wafer is thinned by performing at least one wafer thinning process. The first wafer and a front-side peripheral region of the second wafer may be edge-trimmed by performing a post-bonding edge-trimming process. The bonded assembly may be subsequently diced into bonded semiconductor chips.

Abstract: A semiconductor device includes a first wafer and a second wafer. The semiconductor device includes a seal ring structure comprising a first metal structure in a body of the first wafer, a second metal structure in the body of the first wafer, a third metal structure in a body of the second wafer, and a metal bonding structure including a first set of metal elements coupling the first metal structure and the third metal structure through an interface between the first wafer and the second wafer, and a second set of metal elements coupling the second metal structure and the third metal structure through the interface between the first wafer and the second wafer.

Abstract: Implementations described herein reduce electron-hole pair generation due to silicon dangling bonds in pixel sensors. In some implementations, the silicon dangling bonds in a pixel sensor may be passivated by silicon-fluorine (Si—F) bonding in various portions of the pixel sensor such as a transfer gate contact via or a shallow trench isolation region, among other examples. The silicon-fluorine bonds are formed by fluorine implantation and/or another type of semiconductor processing operation. In some implementations, the silicon-fluorine bonds are formed as part of a cleaning operation using fluorine (F) such that the fluorine may bond with the silicon of the pixel sensor. Additionally, or alternatively, the silicon-fluorine bonds are formed as part of a doping operation in which boron (B) and/or another p-type doping element is used with fluorine such that the fluorine may bond with the silicon of the pixel sensor.

Abstract: Some implementations described herein provide a semiconductor structure. The semiconductor structure includes a first wafer including a first metal structure within a body of the first wafer. The semiconductor structure also includes a second wafer including a second metal structure within a body of the second wafer, where the first wafer is coupled to the second wafer at an interface. The semiconductor structure further includes a metal bonding structure coupled to the first metal structure and the second metal structure and extending through the interface.

Abstract: A semiconductor device includes a first wafer comprising a first portion of a seal ring structure within a body of the first wafer. The semiconductor device includes a second wafer comprising a second portion of the seal ring structure within a body of the second wafer. The second wafer is affixed to the first wafer such that the second portion of the seal ring structure is on the first portion of the seal ring structure. The semiconductor device includes a trench structure comprising a first trench in the first wafer and a second trench in the second wafer, where the first trench and the second trench are on a same side of the seal ring structure.

Abstract: A pixel sensor includes a transfer fin field effect transistor (finFET) to transfer a photocurrent from a photodiode to a drain region. The transfer finFET includes at least a portion of the photodiode, an extension region associated with the drain region, a plurality of channel fins, and a transfer gate at least partially surrounding the channel fins to control the operation of the transfer finFET. In the transfer finFET, the transfer gate is wrapped around (e.g., at least three sides) of each of the channel fins, which provides a greater surface area over which the transfer gate is enabled to control the transfer of electrons. The greater surface area results in greater control over operation of the finFET, which may reduce switching times of the pixel sensor (which enables faster pixel sensor performance) and may reduce leakage current of the pixel sensor relative to a planar transfer transistor.

Abstract: Apparatus and methods for sensing long wavelength light are described herein. A semiconductor device includes: a carrier; a device layer on the carrier; a semiconductor layer on the device layer, and an insulation layer on the semiconductor layer. The semiconductor layer includes isolation regions and pixel regions. The isolation regions are or include a first semiconductor material. The pixel regions are or include a second semiconductor material that is different from the first semiconductor material.

Abstract: A semiconductor structure is provided. The semiconductor structure includes a first semiconductor device. The first semiconductor device includes a first bonding layer formed below a first substrate, a first bonding via formed through the first oxide layer and the first bonding layer, a first dummy pad formed in the first bonding layer. The semiconductor structure includes a second semiconductor device. The second semiconductor device includes a second bonding layer formed over a second substrate, a second bonding via formed through the second bonding layer, and a second dummy pad formed in the second bonding layer. The semiconductor structure includes a bonding structure between the first substrate and the second substrate, wherein the bonding structure includes the first bonding via bonded to the second bonding via and the first dummy pad bonded to the second dummy pad.