Abstract: An image sensor may include high dynamic range imaging pixels having an inner sub-pixel surrounded by an outer sub-pixel. To steer light away from the inner sub-pixel and towards the outer sub-pixel, the high dynamic range imaging pixels may be covered by a toroidal microlens. To mitigate cross-talk caused by high-angled incident light, various microlens arrangements may be used. A toroidal microlens may have planar portions on its outer perimeter. A toroidal microlens may be covered by four additional microlenses, each additional microlens positioned in a respective corner of the pixel. Each pixel may be covered by four microlenses in a 2×2 arrangement, with an opening formed by the space between the four microlenses overlapping the inner sub-pixel.

Abstract: Various embodiments of the present technology may comprise a method and apparatus for an image sensor. The image sensor may comprise a color filter with a convex surface and a corresponding underlying dielectric element. The convex surface of the color filter is parallel to a convex surface of the dielectric element, wherein the convex shape of the color filter is substantially equal to the convex shape of the dielectric element.

Abstract: Various embodiments of the present technology may comprise methods and apparatus for increasing dynamic range of an image sensor. According to an exemplary embodiment, the image sensor comprises a backside-illuminated hybrid bonded stacked chip image senor having a pixel circuit array. A capacitor is formed on each pixel circuit along two adjacent sidewalls of an epitaxial substrate layer facing a deep trench isolation region. The capacitor may also extend along an upper surface of the epitaxial substrate layer.

Abstract: An image sensor may include an array of pixels having a color filter layer. The color filter layer may include colored elements and clear elements. The clear elements may be formed from transparent dielectric material. The color filter layer may include a grid of light-blocking material that forms color filter container structures having an array of openings in which the colored elements and the clear elements are formed. The color filter container structures may be formed from the same transparent dielectric material that forms the clear elements. The color filter container structures may be formed from opaque materials or transparent materials that form structures such as planarization layers, microlenses, or antireflection coatings for the array of pixels. The material used to form the color filter container structures may have a refractive index that is sufficiently high to prevent light from passing between adjacent elements in the color filter layer.

Abstract: Various embodiments of the present technology may comprise a method and apparatus for a biosensor. The biosensor comprises a vertical flow channel that extends through a photodiode, and wherein the photodiode is lateral to the channel's vertical sidewall.

Abstract: Methods of forming an image sensor chip scale package. Implementations may include providing a semiconductor wafer having a pixel array, forming a first cavity through the wafer and/or one or more layers coupled over the wafer, filling the first cavity with a fill material, planarizing the fill material and/or the one or more layers to form a first surface of the fill material coplanar with a first surface of the one or more layers, and bonding a transparent cover over the fill material and the one or more layers. The bond may be a fusion bond between the transparent cover and a passivation oxide; a fusion bond between the transparent cover and an anti-reflective coating; a bond between the transparent cover and an organic adhesive coupled over the fill material, and/or; a bond between a first metallized surface of the transparent cover and a metallized layer coupled over the wafer.

Abstract: Various embodiments of the present technology may comprise a method and apparatus for an image sensor with a thermal equalizer for distributing heat. The method and apparatus may comprise a thermal equalizer disposed between a sensor die and a circuit die to prevent uneven heating of the pixels in the sensor die. The method and apparatus may comprise a thermal equalizer integrated within the circuit die.

Abstract: Several embodiments for semiconductor devices and methods for forming semiconductor devices are disclosed herein. One embodiment is directed to a method for manufacturing a microelectronic imager having a die including an image sensor, an integrated circuit electrically coupled to the image sensor, and electrical connectors electrically coupled to the integrated circuit. The method can comprise covering the electrical connectors with a radiation blocking layer and forming apertures aligned with the electrical connectors through a layer of photo-resist on the radiation blocking layer. The radiation blocking layer is not photoreactive such that it cannot be patterned using radiation. The method further includes etching openings in the radiation blocking layer through the apertures of the photo-resist layer.

Abstract: An image sensor may include high dynamic range imaging pixels having an inner sub-pixel surrounded by an outer sub-pixel. To steer light away from the inner sub-pixel and towards the outer sub-pixel, the high dynamic range imaging pixels may be covered by a toroidal microlens. To mitigate cross-talk caused by high-angled incident light, various microlens arrangements may be used. A toroidal microlens may have planar portions on its outer perimeter. A toroidal microlens may be covered by four additional microlenses, each additional microlens positioned in a respective corner of the pixel. Each pixel may be covered by four microlenses in a 2×2 arrangement, with an opening formed by the space between the four microlenses overlapping the inner sub-pixel.

Abstract: Global shutter imaging pixels may include a charge storage region that receives charge from a respective photodiode. Global shutter imaging pixels may be formed as frontside illuminated imaging pixels or backside illuminated imaging pixels. Shielding charge storage regions from incident light may be important for image sensor performance. To shield charge storage regions in backside illuminated global shutter imaging pixels, shielding structures may be included over the charge storage region. The shielding structures may include backside trench isolation structures, a metal layer formed in a backside trench between backside trench isolation structures, and frontside deep trench isolation structures. The metal layer may have angled portions that reflect light towards the photodiodes.

Abstract: An image sensor package may include a semiconductor wafer having a pixel array, a color filter array (CFA) formed over the pixel array, and one or more lenses formed over the CFA. A light block layer may couple over the semiconductor wafer around a perimeter of the lenses and an encapsulation layer may be coupled around the perimeter of the lenses and over the light block layer. The light block layer may form an opening providing access to the lenses. A mold compound layer may be coupled over the encapsulation layer and the light block layer. A temporary protection layer may be used to protect the one or more lenses from contamination during application of the mold compound and/or during processes occurring outside of a cleanroom environment.

Abstract: Implementations of image sensors may include a silicon layer having a first side and a second side opposite the first side, an opening extending into the silicon layer from the first side of the silicon layer toward the second side, a via extending into the silicon layer from the second side of the silicon layer, and a conductive pad within the opening. The conductive pad may be coupled to the via. The opening may include a fill material. At least a portion of the fill material may form a plane that is substantially parallel with the first side of the silicon layer. The conductive pad may be exposed through an opening in the fill material.

Abstract: Several embodiments for semiconductor devices and methods for forming semiconductor devices are disclosed herein. One embodiment is directed to a method for manufacturing a microelectronic imager having a die including an image sensor, an integrated circuit electrically coupled to the image sensor, and electrical connectors electrically coupled to the integrated circuit. The method can comprise covering the electrical connectors with a radiation blocking layer and forming apertures aligned with the electrical connectors through a layer of photo-resist on the radiation blocking layer. The radiation blocking layer is not photoreactive such that it cannot be patterned using radiation. The method further includes etching openings in the radiation blocking layer through the apertures of the photo-resist layer.

Abstract: Implementations of image sensors may include a silicon layer having a first side and a second side opposite the first side, an opening extending into the silicon layer from the first side of the silicon layer toward the second side, a via extending into the silicon layer from the second side of the silicon layer, and a conductive pad within the opening. The conductive pad may be coupled to the via. The opening may include a fill material. At least a portion of the fill material may form a plane that is substantially parallel with the first side of the silicon layer. The conductive pad may be exposed through an opening in the fill material.

Abstract: Implementations of image sensors may include: a first die including a plurality of detectors adapted to convert photons to electrons; a second die including a plurality of transistors, passive electrical components, or both transistors and passive electrical components; a third die including analog circuitry, logic circuitry, or analog and logic circuitry. The first die may be hybrid bonded to the second die, and the second die may be fusion bonded to the third die. The plurality of transistors, passive electrical components, or transistors and passive electrical components of the second die may be adapted to enable operation of the plurality of detectors of the first die. The analog circuitry, logic circuitry, and analog circuitry and logical circuitry may be adapted to perform signal routing.

Abstract: An image sensor package may include a semiconductor wafer having a pixel array, a color filter array (CFA) formed over the pixel array, and one or more lenses formed over the CFA. A light block layer may couple over the semiconductor wafer around a perimeter of the lenses and an encapsulation layer may be coupled around the perimeter of the lenses and over the light block layer. The light block layer may form an opening providing access to the lenses. A mold compound layer may be coupled over the encapsulation layer and the light block layer. A temporary protection layer may be used to protect the one or more lenses from contamination during application of the mold compound and/or during processes occurring outside of a cleanroom environment.

Abstract: An image sensor package may include a semiconductor wafer having a pixel array, a color filter array (CFA) formed over the pixel array, and one or more lenses formed over the CFA. A light block layer may couple over the semiconductor wafer around a perimeter of the lenses and an encapsulation layer may be coupled around the perimeter of the lenses and over the light block layer. The light block layer may form an opening providing access to the lenses. A mold compound layer may be coupled over the encapsulation layer and the light block layer. A temporary protection layer may be used to protect the one or more lenses from contamination during application of the mold compound and/or during processes occurring outside of a cleanroom environment.

Abstract: Multi-photodiode image pixels may include sub-pixels with differing light sensitivities. Microlenses may be formed over the multi-photodiode image pixels so that light sensitivity of sub-pixels in an outer group of sub-pixels is enhanced. To prevent high angle light incident upon one of the sub-pixels of the image pixel from generating charges in a photosensitive region of another sub-pixel of the image pixel, intra-pixel isolation structures may be formed. Intra-pixel isolation structures may surround, and in some embodiments, overlap the light collecting region of an inner photodiode. When the intra-pixel isolation structures have a different index of refraction than light filtering material formed adjacent to the isolation structures, high angle light incident upon the isolation structures may be reflected back into the sub-pixel it was initially incident upon.

Abstract: Multi-photodiode image pixels may include sub-pixels with differing light sensitivities. Microlenses may be formed over the multi-photodiode image pixels so that light sensitivity of sub-pixels in an outer group of sub-pixels is enhanced. To prevent high angle light incident upon one of the sub-pixels of the image pixel from generating charges in a photosensitive region of another sub-pixel of the image pixel, intra-pixel isolation structures may be formed. Intra-pixel isolation structures may surround, and in some embodiments, overlap the light collecting region of an inner photodiode. When the intra-pixel isolation structures have a different index of refraction than light filtering material formed adjacent to the isolation structures, high angle light incident upon the isolation structures may be reflected back into the sub-pixel it was initially incident upon.

Abstract: An image sensor may include an array of pixels having a color filter layer. The color filter layer may include colored elements and clear elements. The clear elements may be formed from transparent dielectric material. The color filter layer may include a grid of light-blocking material that forms color filter container structures having an array of openings in which the colored elements and the clear elements are formed. The color filter container structures may be formed from the same transparent dielectric material that forms the clear elements. The color filter container structures may be formed from opaque materials or transparent materials that form structures such as planarization layers, microlenses, or antireflection coatings for the array of pixels. The material used to form the color filter container structures may have a refractive index that is sufficiently high to prevent light from passing between adjacent elements in the color filter layer.