An image sensor may include a plurality of pixels that each contain a photodiode. The pixels may include deep photodiodes for near infrared applications. The photodiodes may be formed by growing doped epitaxial silicon in trenches formed in a substrate. The doped epitaxial silicon may be doped with phosphorus or arsenic. The pixel may include additional n-wells formed by implanting ions in the substrate. Isolation regions formed by implanting boron ions may isolate the n-wells and doped epitaxial silicon. The doped epitaxial silicon may be formed at temperatures between 500 C. and 550 C. After forming the doped epitaxial silicon, laser annealing may be used to activate the ions. Chemical mechanical planarization may also be performed to ensure that the doped epitaxial silicon has a flat and planar surface for subsequent processing.

A global shutter image sensor of a back-illuminated type includes a semiconductor substrate and pixels. Each pixel includes a photosensitive area, a storage area, a readout area and areas for transferring charges between these different areas. The image sensor includes, for each pixel, a protector extending at least partly into the substrate from the back of the substrate to ensure that the storage area is protected against back illumination.

A TFT and manufacturing method thereof, an array substrate and manufacturing method thereof, an X-ray detector and a display device are disclosed. The manufacturing method includes: forming a gate-insulating-layer thin film (3), a semiconductor-layer thin film (4) and a passivation-shielding-layer thin film (5) successively; forming a pattern (5) that includes a passivation shielding layer through one patterning process, so that a portion, sheltered by the passivation shielding layer, of the semiconductor-layer thin film forms a pattern of an active layer (4a); and performing an ion doping process to a portion, not sheltered by the passivation shielding layer, of the semiconductor-layer thin film to form a pattern comprising a source electrode (4c) and a drain electrode (4b). The source electrode (4c) and the drain electrode (4b) are disposed on two sides of the active layer (4a) respectively and in a same layer as the active layer (4a). The manufacturing method can reduce the number of patterning processes and improve the performance of the thin film transistor in the array substrate.

The present disclosure relates to a method of forming a masking structure having a trench with a high aspect ratio, and an associated structure. In some embodiments, the method is performed by forming a first material over a substrate. The first material is selectively etched and a second material is formed onto the substrate at a position abutting sidewalls of the first material, resulting in a pillar of sacrificial material surrounded by a masking material. The pillar of sacrificial material is removed, resulting in a masking layer having a trench that extends into the masking material. Using the pillar of sacrificial material during formation of the trench allows the trench to have a high aspect ratio. For example, the sacrificial material allows for a plurality of masking layers to be iteratively formed to have laterally aligned openings that collectively form a trench extending through the masking layers.

Provided is a complementary metal-oxide-semiconductor (CMOS) image sensor. The CMOS image sensor can include a substrate having a first device isolation layer defining and dividing a first active region and a second active region, a photodiode disposed in the substrate and can be configured to vertically overlap the first device isolation layer, a transfer gate electrode can be disposed in the first active region and can be configured to vertically overlap the photodiode, and a floating diffusion region can be in the first active region. The transfer gate electrode can be buried in the substrate.

A solid-state image pickup device includes a semiconductor substrate in which photoelectric conversion units are arranged. An insulator is disposed on the semiconductor substrate. The insulator has holes associated with the respective photoelectric conversion units. Members are arranged in the respective holes. A light-shielding member is disposed on the opposite side of one of the members from the semiconductor substrate, such that only the associated photoelectric conversion unit is shielded from light. In the solid-state image pickup device, the holes are simultaneously formed and the members are simultaneously formed.

A semiconductor device including a semiconductor layer that includes an active region, semiconductor elements that are formed using the active region, connection regions that are obtained by metalizing parts of the semiconductor layer in an island shape isolated from the active region, an insulation film that is formed to cover one main surface side of the semiconductor layer, electrodes that are disposed to face the semiconductor elements and the connection regions via the insulation film, and contacts that penetrate through the insulation film to be selectively formed in portions according to necessity among portions that connect the semiconductor elements or the connection regions to the electrodes.

A solid-state imaging device includes a plurality of photoelectric conversion portions each provided in a semiconductor substrate and receives incident light through a light sensing surface, and a pixel separation portion provided to electrically separate a plurality of pixels. At least a pinning layer and a light shielding layer are provided in an inner portion of a trench provided on a side portion of each of the photoelectric conversion portions in an incident surface side, the trench includes a first trench and a second trench formed to be wider than the first trench in a portion shallower than the first trench, the pinning layer is formed in an inner portion of the first trench to cover an inside surface of the second trench, and the light shielding layer is formed to bury an inner portion of the second trench at least via the pinning layer.

An image sensor including a control circuit and a plurality of pixels, each pixel including: a photosensitive area, a substantially rectangular storage area adjacent to the photosensitive area, and a read area; first and second insulated vertical electrodes electrically connected to each other, opposite each other, and delimiting the storage area, the first electrode extending between the storage area and the photosensitive area, the second electrode including a bent extension opposite a first end of the first electrode, the storage area emerging onto the photosensitive area on the side of the first end, the control circuit being capable of applying a first voltage to the first and second electrodes to perform a charge transfer, and a second voltage to block said transfer.

An image sensor structure is provided. The image sensor structure includes a substrate including a first light sensing region and a second light sensing region. The image sensor structure further includes an isolation structure formed through the substrate to separate the first light sensing region and the second light sensing region and a first source/drain structure and a second source/drain structure formed at a front side of the substrate. In addition, the first source/drain structure and the second source/drain structure are located at opposite sides of the isolation structure. The image sensor structure further includes a contact formed over the isolation structure, a portion of the first source/drain structure, and a portion of the second source/drain structure.