Abstract: A multi-pixel detector of an image sensor is described. The multi-pixel detector includes a first photodiode region disposed within a semiconductor substrate to form a first pixel, a second photodiode region disposed within the semiconductor substrate to form a second pixel adjacent to the first pixel, and a partial isolation structure extending from a first side of the semiconductor substrate towards a second side of the semiconductor substrate between the first photodiode region and the second photodiode region. A length of a lateral portion of the partial isolation structure between the first photodiode region and the second photodiode region is less than a lateral length of the first photodiode region.

Abstract: An image sensor pixel array comprises a plurality of image pixel units to gather image information and a plurality of phase detection auto-focus (PDAF) pixel units to gather phase information. Each of the PDAF pixel units includes two of first image sensor pixels covered by two micro-lenses, respectively. Each of the image pixel units includes four of second image sensor pixels adjacent to each other, wherein each of the second image sensor pixels is covered by an individual micro-lens. A coating layer is disposed on the micro-lenses and forms a flattened surface across the whole image sensor pixel array. A PDAF micro-lens is formed on the coating layer to cover the first image sensor pixels.

Abstract: A multi-pixel detector of an image sensor is described. The multi-pixel detector includes a first photodiode region disposed within a semiconductor substrate to form a first pixel, a second photodiode region disposed within the semiconductor substrate to form a second pixel adjacent to the first pixel, and a partial isolation structure extending from a first side of the semiconductor substrate towards a second side of the semiconductor substrate between the first photodiode region and the second photodiode region. A length of a lateral portion of the partial isolation structure between the first photodiode region and the second photodiode region is less than a lateral length of the first photodiode region.

Abstract: An image sensor pixel array comprises a plurality of image pixel units to gather image information and a plurality of phase detection auto-focus (PDAF) pixel units to gather phase information. Each of the PDAF pixel units includes two of first image sensor pixels covered by two micro-lenses, respectively. Each of the image pixel units includes four of second image sensor pixels adjacent to each other, wherein each of the second image sensor pixels is covered by an individual micro-lens. A coating layer is disposed on the micro-lenses and forms a flattened surface across the whole image sensor pixel array. A PDAF micro-lens is formed on the coating layer to cover the first image sensor pixels.

Abstract: A backside-illuminated color image sensor with crosstalk-suppressing color filter array includes (a) a silicon layer including an array of photodiodes and (b) a color filter layer on the light-receiving surface of the silicon layer, wherein the color filter layer includes (i) an array of color filters cooperating with the array of photodiodes to form a respective array of color pixels and (ii) a light barrier grid disposed between the color filters to suppress transmission of light between adjacent ones of the color filters. The light barrier is spatially non-uniform across the color filter layer to account for variation of chief ray angle across the array of color filters.

Abstract: A backside-illuminated color image sensor with crosstalk-suppressing color filter array includes (a) a silicon layer including an array of photodiodes and (b) a color filter layer on the light-receiving surface of the silicon layer, wherein the color filter layer includes (i) an array of color filters cooperating with the array of photodiodes to form a respective array of color pixels and (ii) a light barrier grid disposed between the color filters to suppress transmission of light between adjacent ones of the color filters.

Abstract: A method of fabricating a pixel array includes forming a transistor network along a frontside of a semiconductor substrate. A contact element is formed for every pixel in the pixel array that is electrically coupled to a transistor within the transistor network. An interconnect layer is formed upon the frontside to control the transistor network with a dielectric that covers the contact element. A cavity is formed in the interconnect layer. A conductive layer is formed along cavity walls of the cavity and a dielectric layer is formed over the conductive layer within the cavity. A photosensitive semiconductor material is deposited over the dielectric layer within the cavity. An electrode cavity is formed that extends into the contact element. The electrode cavity is at least partially filled with a conductive material to form an electrode. The electrode, the conductive layer, and the photosensitive semiconductor material form a photosensitive capacitor.

Abstract: An image sensor pixel includes a photodiode disposed in a semiconductor material, and doped regions surrounding the photodiode, at least in part. The doped regions include a doped portion of the semiconductor material. Deep trench isolation structures are disposed in the doped regions, and surround the photodiode at least in part. The deep trench isolation structures include a SiGe layer disposed on side walls of the deep trench isolation structures, a high-k dielectric disposed on the SiGe layer, and a filler material.

Abstract: A method of fabricating a pixel array includes forming a transistor network along a frontside of a semiconductor substrate. A contact element is formed for every pixel in the pixel array that is electrically coupled to a transistor within the transistor network. An interconnect layer is formed upon the frontside to control the transistor network with a dielectric that covers the contact element. A cavity is formed in the interconnect layer. A conductive layer is formed along cavity walls of the cavity and a dielectric layer is formed over the conductive layer within the cavity. A photosensitive semiconductor material is deposited over the dielectric layer within the cavity. An electrode cavity is formed that extends into the contact element. The electrode cavity is at least partially filled with a conductive material to form an electrode. The electrode, the conductive layer, and the photosensitive semiconductor material form a photosensitive capacitor.

Abstract: An image sensor includes a semiconductor layer with a plurality of photodiodes. A plurality of isolation structures is disposed in the back side of the semiconductor layer between individual photodiodes in the plurality of photodiodes. The plurality of isolation structures extend into the back side of the semiconductor layer a first depth and extend out of the back side of the semiconductor layer a first length. A plurality of light filters is disposed proximate to the back side of the semiconductor layer such that the plurality of isolation structures is disposed between individual light filters in the plurality of light filters. An antireflection coating is also disposed between the semiconductor layer and the plurality of light filters.

Abstract: An image sensor pixel, and image sensor, and a method of fabricating the same is disclosed. The image pixel includes a photosensitive capacitor and a transistor network. The photosensitive capacitor includes an electrode, a conductive layer, a dielectric layer, and a photosensitive semiconductor material. The conductive layer is disposed around the electrode and the dielectric layer is formed between the conductive layer and the electrode. The photosensitive semiconductor material is for generating an image signal in response to image light and is disposed between the dielectric layer and the electrode. The transistor network is coupled to readout the image signal from the electrode of the photosensitive capacitor.

Abstract: An image sensor pixel, and image sensor, and a method of fabricating the same is disclosed. The image pixel includes a photosensitive capacitor and a transistor network. The photosensitive capacitor includes an electrode, a conductive layer, a dielectric layer, and a photosensitive semiconductor material. The conductive layer is disposed around the electrode and the dielectric layer is formed between the conductive layer and the electrode. The photosensitive semiconductor material is for generating an image signal in response to image light and is disposed between the dielectric layer and the electrode. The transistor network is coupled to readout the image signal from the electrode of the photosensitive capacitor.

Abstract: An image sensor includes a semiconductor layer with a plurality of photodiodes. A plurality of isolation structures is disposed in the back side of the semiconductor layer between individual photodiodes in the plurality of photodiodes. The plurality of isolation structures extend into the back side of the semiconductor layer a first depth and extend out of the back side of the semiconductor layer a first length. A plurality of light filters is disposed proximate to the back side of the semiconductor layer such that the plurality of isolation structures is disposed between individual light filters in the plurality of light filters. An antireflection coating is also disposed between the semiconductor layer and the plurality of light filters.