A method for manufacturing one or more optical sensor packages includes forming a bonded wafer by bonding (i) a device wafer comprising a plurality of optical sensing pixels and (ii) a circuit wafer comprising application-specific-integrated-circuit configured to operate the optical sensing pixels, where the bonded wafer includes a device-wafer surface and a circuit-wafer surface. The method also includes forming a plurality of microlens arrays over the device-wafer surface, where each microlens of the microlens arrays corresponds to a particular optical sensing pixel. The method also includes forming a plurality of module-lens structures over the plurality of microlens arrays, where each module-lens structure corresponds to a particular microlens array of the plurality of microlens arrays. The method also includes forming electrical contacts over the circuit-wafer surface to establish electrical connections to the plurality of optical sensing pixels and the application-specific-integrated-circuit.

A semiconductor device includes a pixel array comprising a first pixel and a second pixel. The semiconductor device includes a metal structure overlying a portion of a substrate between the first pixel and the second pixel. The semiconductor device includes a first barrier layer adjacent a sidewall of the metal structure. The semiconductor device includes a passivation layer adjacent a sidewall of the first barrier layer. The first barrier layer is between the passivation layer and the metal structure.

A solid-state imaging device includes: a first semiconductor substrate including a photoelectric conversion element; and a second semiconductor substrate including at least a part of a peripheral circuit arranged in a main face of the second semiconductor substrate, the peripheral circuit generating a signal based on the charge of the photoelectric conversion element, a main face of the first semiconductor substrate and the main face of the second semiconductor substrate being opposed to each other with sandwiching a wiring structure therebetween; a pad to be connected to an external terminal; and a protection circuit electrically connected to the pad and to the peripheral circuit, wherein the protection circuit is arranged in the main face of the second semiconductor substrate.

An image sensor includes a substrate including a first surface and a second surface which is opposite to the first portion, and a pixel isolation portion provided in the substrate and configured to isolate unit pixels from each other. The pixel isolation portion includes a first filling insulation pattern extending from the first surface toward the second surface and having an air gap region, the first filling insulation pattern including a first sidewall and a second sidewall which is opposite to the first sidewall, a conductive structure including a first portion on the first sidewall, a second portion on the second sidewall, and a connection portion connecting the first portion and the second portion, and an insulating liner provided between the first portion and the substrate and between the second portion and the substrate.

Some embodiments relate to an integrated circuit light sensor device. The integrated circuit light sensor device includes a semiconductor substrate, as well as a plurality of first light-absorption regions and a plurality of second light-absorption regions located in the semiconductor substrate. Each of the first light-absorption regions includes an implantation region of the semiconductor substrate. The implantation region and the semiconductor substrate form at least a portion of a corresponding one of a plurality of first photodetectors for a first light wavelength band. Each of the second light-absorption regions includes a semiconductor material different from the semiconductor substrate. The semiconductor material forms at least a portion of a corresponding one of a plurality of second photodetectors for a second light wavelength band different from the first light wavelength band.

Implementations of a pad for an image sensor may include a pad base coupled in a pad opening formed in an image sensor die and a layer of metal directly coupled to the pad base extending to a top surface of the pad opening. The pad base may directly couple with a first metallization layer of the image sensor die.

To improve reliability of a solid-state imaging apparatus. A solid-state imaging apparatus includes: a chip; and a transparent member. A solid-state image sensor is formed in the chip. The transparent member is directly joined to the chip via a projecting portion. The projecting portion of the transparent member is formed so as to maintain a gap between the transparent member and an imaging region of the solid-state image sensor of the chip. A protective film may be formed on a semiconductor substrate via an anti-reflection film. A color filter or an on-chip lens may be formed for each pixel in the imaging region of the solid-state image sensor of the chip.

A solid-state imaging element including a lens array in which micro lenses are formed in an alignment, a flattening layer formed on the lens array, and a diffraction grating part including a thermosetting resin, has diffraction gratings, and is provided on the flattening layer. A solid-state imaging element including a lens array in which micro lenses are in an alignment, a flattening layer formed on the lens array, and a diffraction grating part including a base that covers the entire upper surface of the flattening layer, and diffraction gratings provided so as to protrude from the base.

Various embodiments of the present application are directed towards an image sensor including a wavelength tunable narrow band filter, as well as methods for forming the image sensor. In some embodiments, the image sensor includes a substrate, a first photodetector, a second photodetector, and a filter. The first and second photodetectors neighbor in the substrate. The filter overlies the first and second photodetectors and includes a first distributed Bragg reflector (DBR), a second DBR, and a first interlayer between the first and second DBRs. A thickness of the first interlayer has a first thickness value overlying the first photodetector and a second thickness value overlying the second photodetector. In some embodiments, the filter is limited to a single interlayer. In other embodiments the filter further includes a second interlayer defining columnar structures embedded in the first interlayer and having a different refractive index than the first interlayer.

Image sensors and methods of manufacturing image sensors are provided. One such method includes forming a structure that includes a semiconductor layer extending from a front side to a back side, and a capacitive insulation wall extending through the semiconductor layer. The capacitive insulation wall includes first and second insulating walls separated by a region of a conductor or a semiconductor material. Portions of the semiconductor layer and the region of the conductor or semiconductor material are selectively etched, and the first and second insulating walls have portions protruding outwardly beyond a back side of the semiconductor layer and of the region of the conductor or semiconductor material. A dielectric passivation layer is deposited on the back side of the structure, and portions of the dielectric passivation layer are locally removed on a back side of the protruding portions of the first and second insulating walls.