Abstract: The present disclosure relates to an image sensor having autofocus function and associated methods. In some embodiments, the integrated circuit has a photodiode array with a plurality of photodiodes disposed within a semiconductor substrate and a composite grid overlying the photodiode array and having a first plurality of openings and a second plurality of openings extending vertically through the composite grid. The integrated circuit further has an image sensing pixel array with a plurality of color filters disposed in the first plurality of openings. The integrated circuit further has a phase detection pixel array having a plurality of phase detection components that are smaller than the plurality of color filters and that have a low refractive index (low-n) material with a refractive index (n) smaller than a refractive index of the plurality of color filters, wherein the phase detection components are disposed in the second plurality of openings.

Abstract: A back side image sensor and method of manufacture are provided. In an embodiment a bottom anti-reflective coating is formed over a substrate, and a metal shield layer is formed over the bottom anti-reflective coating. The metal shield layer is patterned to form a grid pattern over a sensor array region of the substrate, and a first dielectric layer and a second dielectric layer are formed to at least partially fill in openings within the grid pattern.

Abstract: An image sensor includes a substrate, a plurality of visible light photosensitive devices, an infrared photosensitive device, a plurality of color filters, an infrared band-pass filter, a micro-lens layer and an infrared filter layer. The plurality of visible light photosensitive devices and the infrared photosensitive device are disposed in the substrate, wherein the plurality of visible light photosensitive devices and the infrared photosensitive device are arranged in an array. The plurality of color filters are respectively disposed to cover the plurality of visible light photosensitive device. In addition, the infrared band-pass filter disposed to cover the infrared photosensitive device. Furthermore, the micro-lens layer is disposed on the plurality of color filters and the infrared band-pass filter. The infrared filter layer is disposed to cover the plurality of visible light photosensitive device.

Abstract: An image sensor for high angular response discrimination is provided. A plurality of pixels comprises a phase detection autofocus (PDAF) pixel and an image capture pixel. Pixel sensors of the pixels are arranged in a semiconductor substrate. A grid structure is arranged over the semiconductor substrate, laterally surrounding color filters of the pixels. Microlenses of the pixels are arranged over the grid structure, and comprise a PDAF microlens of the PDAF pixel and an image capture microlens of the image capture pixel. The PDAF microlens comprises a larger optical power than the image capture microlens, or comprises a location or shape so a PDAF receiving surface of the PDAF pixel has an asymmetric profile. A method for manufacturing the image sensor is also provided.

Abstract: An image sensor includes a substrate, a plurality of visible light photosensitive devices, an infrared photosensitive device, a plurality of color filters, an infrared band-pass filter, a micro-lens layer and an infrared filter layer. The plurality of visible light photosensitive devices and the infrared photosensitive device are disposed in the substrate, wherein the plurality of visible light photosensitive devices and the infrared photosensitive device are arranged in an array. The plurality of color filters are respectively disposed to cover the plurality of visible light photosensitive device. In addition, the infrared band-pass filter disposed to cover the infrared photosensitive device. Furthermore, the micro-lens layer is disposed on the plurality of color filters and the infrared band-pass filter. The infrared filter layer is disposed to cover the plurality of visible light photosensitive device.

Abstract: BSI image sensors and methods. In an embodiment, a substrate is provided having a sensor array and a periphery region and having a front side and a back side surface; a bottom anti-reflective coating (BARC) is formed over the back side to a first thickness, over the sensor array region and the periphery region; forming a first dielectric layer over the BARC; a metal shield is formed; selectively removing the metal shield from over the sensor array region; selectively removing the first dielectric layer from over the sensor array region, wherein a portion of the first thickness of the BARC is also removed and a remainder of the first thickness of the BARC remains during the process of selectively removing the first dielectric layer; forming a second dielectric layer over the remainder of the BARC and over the metal shield; and forming a passivation layer over the second dielectric layer.

Abstract: Provided is an image sensor device. The image sensor device includes a substrate having a front side and a back side. The image sensor includes first and second radiation-detection devices that are disposed in the substrate. The first and second radiation-detection devices are operable to detect radiation waves that enter the substrate through the back side. The image sensor also includes an anti-reflective coating (ARC) layer. The ARC layer is disposed over the back side of the substrate. The ARC layer has first and second ridges that are disposed over the first and second radiation-detection devices, respectively. The first and second ridges each have a first refractive index value. The first and second ridges are separated by a substance having a second refractive index value that is less than the first refractive index value.

Abstract: A semiconductor structure for back side illumination (BSI) pixel sensors is provided. Photodiodes are arranged within a semiconductor substrate. A metal grid overlies the semiconductor substrate and is made up of metal grid segments that surround outer perimeters of the photodiodes, respectively, such that first openings within the metal grid overlie the photodiodes, respectively. A low-n grid is made up of low-n grid segments that surround the respective outer perimeters of the photodiodes, respectively, such that second openings within the low-n grid overlie the photodiodes, respectively. Color filters are arranged in the first and second openings of the photodiodes and have a refractive index greater than a refractive index of the low-n grid. A substrate isolation grid extends into the semiconductor substrate and is made up of isolation grid segments that surround outer perimeters of the photodiodes, respectively. A method for manufacturing the BSI pixel sensors is also provided.

Abstract: An image sensor includes a substrate, photosensitive devices, a color filter layer, a micro-lens layer and an infrared filter layer. The photosensitive devices are disposed in the substrate. The color filter layer is disposed to cover the photosensitive devices. The micro-lens layer is disposed on the color filter layer. The infrared filter layer directly covers the micro-lens layer.

Abstract: A back side image sensor and method of manufacture are provided. In an embodiment a bottom anti-reflective coating is formed over a substrate, and a metal shield layer is formed over the bottom anti-reflective coating. The metal shield layer is patterned to form a grid pattern over a sensor array region of the substrate, and a first dielectric layer and a second dielectric layer are formed to at least partially fill in openings within the grid pattern.

Abstract: A semiconductor structure for back side illumination (BSI) pixel sensors is provided. Photodiodes are arranged within a semiconductor substrate. A metal grid overlies the semiconductor substrate and is made up of metal grid segments that surround outer perimeters of the photodiodes, respectively, such that first openings within the metal grid overlie the photodiodes, respectively. A low-n grid is made up of low-n grid segments that surround the respective outer perimeters of the photodiodes, respectively, such that second openings within the low-n grid overlie the photodiodes, respectively. Color filters are arranged in the first and second openings of the photodiodes and have a refractive index greater than a refractive index of the low-n grid. A substrate isolation grid extends into the semiconductor substrate and is made up of isolation grid segments that surround outer perimeters of the photodiodes, respectively. A method for manufacturing the BSI pixel sensors is also provided.

Abstract: A semiconductor structure for back side illumination (BSI) pixel sensors is provided. Photodiodes are arranged within a semiconductor substrate. A composite grid includes a metal grid and a low refractive index (low-n) grid. The metal grid includes first openings overlying the semiconductor substrate and corresponding to ones of the photodiodes. The low-n grid includes second openings overlying the semiconductor substrate and corresponding to ones of the photodiodes. Color filters are arranged in the first and second openings of the corresponding photodiodes and have a refractive index greater than a refractive index of the low-n grid. Upper surfaces of the color filters are offset relative to an upper surface of the composite grid. A method for manufacturing the BSI pixel sensors is also provided.

Abstract: A semiconductor structure for back side illumination (BSI) pixel sensors is provided. Photodiodes are arranged within a semiconductor substrate. A composite grid includes a metal grid and a low refractive index (low-n) grid. The metal grid includes first openings overlying the semiconductor substrate and corresponding to ones of the photodiodes. The low-n grid includes second openings overlying the semiconductor substrate and corresponding to ones of the photodiodes. Color filters are arranged in the first and second openings of the corresponding photodiodes and have a refractive index greater than a refractive index of the low-n grid. Upper surfaces of the color filters are offset relative to an upper surface of the composite grid. A method for manufacturing the BSI pixel sensors is also provided.

Abstract: An image sensor includes a substrate, photosensitive devices, a color filter layer, a micro-lens layer and an infrared filter layer. The photosensitive devices are disposed in the substrate. The color filter layer is disposed to cover the photosensitive devices. The micro-lens layer is disposed on the color filter layer. The infrared filter layer directly covers the micro-lens layer.

Abstract: BSI image sensors and methods. In an embodiment, a substrate is provided having a sensor array and a periphery region and having a front side and a back side surface; a bottom anti-reflective coating (BARC) is formed over the back side to a first thickness, over the sensor array region and the periphery region; forming a first dielectric layer over the BARC; a metal shield is formed; selectively removing the metal shield from over the sensor array region; selectively removing the first dielectric layer from over the sensor array region, wherein a portion of the first thickness of the BARC is also removed and a remainder of the first thickness of the BARC remains during the process of selectively removing the first dielectric layer; forming a second dielectric layer over the remainder of the BARC and over the metal shield; and forming a passivation layer over the second dielectric layer.

Abstract: A photo diode includes a pixel unit, a photo conversion layer, and a dielectric layer. The pixel unit includes a pair of pixels. The photo conversion layer is above the pixel unit and has a pair of portions, each of which corresponds to a respective one of the pixels. The dielectric layer is between the portions of the photo conversion layer. A method of manufacturing the photo diode is also disclosed.

Abstract: A back side image sensor and method of manufacture are provided. In an embodiment a bottom anti-reflective coating is formed over a substrate, and a metal shield layer is formed over the bottom anti-reflective coating. The metal shield layer is patterned to form a grid pattern over a sensor array region of the substrate, and a first dielectric layer and a second dielectric layer are formed to at least partially fill in openings within the grid pattern.

Abstract: An image sensor includes a substrate, photosensitive devices, a color filter layer, a micro-lens layer and an infrared filter layer. The photosensitive devices are disposed in the substrate. The color filter layer is disposed to cover the photosensitive devices. The micro-lens layer is disposed on the color filter layer. The infrared filter layer directly covers the micro-lens layer.

Abstract: A method for forming a photo diode is provided. The method includes: forming a first pair of electrodes and a second pair of electrodes over a substrate by using a conductive layer; forming a dielectric layer over the substrate; patterning the dielectric layer over the substrate; forming a photo conversion layer over the substrate; and forming a color filter layer over the photo conversion layer, wherein at least a portion of the dielectric layer separates a first portion of the color filter layer corresponding to a first pixel from a second portion of the color filter layer corresponding to a second pixel, and a refractive index of the dielectric layer is lower than a refractive index of the color filter layer, wherein the first pair of electrodes corresponds to the first pixel and the second pair of electrodes corresponds to the second pixel.

Abstract: An embodiment method for forming an image sensor includes forming an anti-reflective coating over a surface of a semiconductor supporting a photodiode, forming an etching stop layer over the anti-reflective coating, forming a buffer oxide over the etching stop layer, and selectively removing a portion of the buffer oxide through etching, the etching stop layer protecting the anti-reflective coating during the etching. An embodiment image sensor includes a semiconductor disposed in an array region and in a periphery region, the semiconductor supporting a photodiode in the array region, an anti-reflective coating disposed over a surface of the semiconductor, an etching stop layer disposed over the anti-reflective coating, a thickness of the etching stop layer over the photodiode in the array region less than a thickness of the etching stop layer in the periphery region, and a buffer oxide disposed over the etching stop layer in the periphery region.