The present disclosure relates to a solid-state imaging device, an electronic apparatus, and a manufacturing method that are designed to further increase conversion efficiency.

A solid-state imaging device includes a pixel in which element separation is realized by a first trench element separation region having a trench structure in a region between an FD unit and an amplifying transistor among element separation elements separating the elements constituting the pixel from one another, and a second trench element separation region having a trench structure in a region other than the region between the FD unit and the amplifying transistor among the element separation regions separating the elements constituting the pixel from one another, and the first trench element separation region is deeper than the second trench element separation region. The present technology can be applied to CMOS image sensors, for example.

In a solid-state imaging device including a plurality of pixels each pixel including a plurality of photodiodes, it is prevented that an incidence angle of incident light on the solid-state imaging device becomes large in a pixel in an end of the solid-state imaging device, causing a difference in output between the two photodiodes in the pixel, and thus autofocus detection accuracy is deteriorated. Photodiodes extending in a longitudinal direction of a pixel allay section are provided in each pixel. The photodiodes in the pixel are arranged in a direction orthogonal to the longitudinal direction of the pixel allay section.

A semiconductor device includes a first semiconductor layer; an insulation member layer formed on the first semiconductor layer; a transistor disposed in an upper portion of the insulation member layer; a first interlayer insulation film covering the transistor; a layered member including a wiring layer formed on the first interlayer insulation film and a second interlayer insulation film; and a first penetrating electrode penetrating through the insulation member layer, the first interlayer insulation film, and the layered member. The first penetrating electrode is electrically connected only to the first semiconductor layer.

There is provided an imaging device that includes photovoltaic type pixels that have photoelectric conversion regions generating photovoltaic power for each pixel depending on irradiation light; and an element isolation region that is provided between the photoelectric conversion regions of adjacent pixels and in a state of substantially surrounding the photoelectric conversion region.

A method of manufacturing an image sensor device includes, in a first manufacturing facility, forming a first set of patterned silicon, metal, and insulating layers on a glass substrate, forming an electrical and mechanical protection layer over the first set of patterned silicon, metal, and insulating layers, and, in a second manufacturing facility, removing the electrical and mechanical protection layer, forming a second set of patterned silicon, metal, and insulating layers over the first set of patterned silicon, metal, and insulating layers, forming a plurality of photosensors in communication with at least the second set of patterned silicon, metal, and insulating layers to form an unpassivated image sensor device, and forming a passivation layer over the unpassivated image sensor device. The materials used in the first set of layers and second set of layers can be completely or partially different.

Provided herein is a digital x-ray detector and a method for repairing a bad pixel thereof, the detector including a substrate; a gate line and a data line formed on the substrate such that the gate line and the data line intersect each other to form a pixel domain; a thin film transistor formed within the pixel domain such that the thin film transistor is adjacent to a portion where the gate line and the data line intersect each other, the thin film transistor including a gate electrode, an active layer, a source electrode and a drain electrode; a PIN diode which is formed within the pixel domain and which includes a lower electrode connected to the source electrode of the thin film transistor, a PIN layer formed on the lower electrode, and an upper electrode formed on the PIN layer; a bias line connected to the upper electrode of the PIN diode; and a scintillator arranged above the PIN diode, wherein on at least one of a surface of the drain electrode which faces the PIN diode and a surface of the PIN diode which faces the drain electrode, a groove is formed such that it expands a distance between the drain electrode and the PIN diode.

An epitaxial grown avalanche photodiode (APD), the avalanche photodiode comprising an anode, a cathode, an absorber, and a doped multiplier. The absorber and the doped multiplier are about between the cathode and the anode. The doped multiplier has a multiplier dopant concentration. The doped multiplier substantially depleted during operation of the epitaxial grown photodiode. The doped multiplier may comprise of a plurality of multiplication regions, each of the multiplication regions substantially depleted during operation of the avalanche photodiode.

A semiconductor device includes a semiconductor substrate, a radiation-sensing region, at least one isolation structure, and a doped passivation layer. The radiation-sensing region is present in the semiconductor substrate. The isolation structure is present in the semiconductor substrate and adjacent to the radiation-sensing region. The doped passivation layer at least partially surrounds the isolation structure in a substantially conformal manner.

A backside illuminated image sensor with an array of pixels formed in a substrate is provided. To improve surface planarity, bond pads formed at the periphery of the array of pixels may be recessed into a back surface of the substrate. The bond pads may be recessed into a semiconductor layer of the substrate, may be recessed into a window in the semiconductor layer, or may be recessed in a passivation layer and covered with non-conductive material such as resin. In order to further improve surface planarity, a window may be formed in the semiconductor layer at the periphery of the array of pixels, or scribe region, over alignment structures. By providing an image sensor with improved surface planarity, device yield and time-to-market may be improved, and window framing defects and microlens/color filter non-uniformity may be reduced.

A semiconductor device has a chip region including a back-side illumination type photoelectric conversion element, a mark-like appearance part, a pad electrode, and a coupling part. The mark-like appearance part includes an insulation film covering the entire side surface of a trench part formed in a semiconductor substrate. The pad electrode is arranged at a position overlapping the mark-like appearance part. The coupling part couples the pad electrode and mark-like appearance part. At least a part of the pad electrode on the other main surface side of the substrate is exposed through an opening reaching the pad electrode from the other main surface side of the substrate. The mark-like appearance part and coupling part are arranged to at least partially surround the outer circumference of the opening in plan view.