A high sensitivity image sensor comprises an epitaxial layer of silicon that is intrinsic or lightly p doped (such as a doping level less than about 10.sup.13 cm.sup.3). CMOS or CCD circuits are fabricated on the front-side of the epitaxial layer. Epitaxial p and n type layers are grown on the backside of the epitaxial layer. A pure boron layer is deposited on the n-type epitaxial layer. Some boron is driven a few nm into the n-type epitaxial layer from the backside during the boron deposition process. An anti-reflection coating may be applied to the pure boron layer. During operation of the sensor a negative bias voltage of several tens to a few hundred volts is applied to the boron layer to accelerate photo-electrons away from the backside surface and create additional electrons by an avalanche effect. Grounded p-wells protect active circuits as needed from the reversed biased epitaxial layer.

A semiconductor device is disclosed, which includes: at least one a device layer being a crystallized layer for example including: a superlattice layer and/or a layer of group III-V semiconductor materials; and a passivation structure comprising one or more layers wherein at least one layer of the passivation structure is a passivation layer grown in-situ in a crystallized form on top of the device layer, and at least one of the one or more layers of the passivation structure includes material having a high density of surface states which forces surface pinning of an equilibrium Fermi level within a certain band gap of the device layer, away from its conduction and valence bands.

A method for manufacturing a BSI image sensor includes following steps: A substrate is provided. The substrate includes a front side and a back side opposite to the front side. The substrate further includes a plurality of isolation structures and a plurality of sensing elements formed therein. Next, the isolation structures are exposed from the back side of the substrate. Subsequently, a thermal treatment is performed to the back side of the substrate to form a plurality of cambered surfaces on the back side of the substrate. The cambered surfaces are formed correspondingly to the sensing elements, respectively.

A sensor package that includes a substrate with opposing first and second surfaces. A plurality of photo detectors are formed on or under the first surface and configured to generate one or more signals in response to light incident on the first surface. A plurality of contact pads are formed at the first surface and are electrically coupled to the plurality of photo detectors. A plurality of holes are each formed into the second surface and extending through the substrate to one of the contact pads. Conductive leads each extend from one of the contact pads, through one of the plurality of holes, and along the second surface. The conductive leads are insulated from the substrate. One or more trenches are formed into a periphery portion of the substrate each extending from the second surface to the first surface. Insulation material covers sidewalls of the one or more trenches.

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.

An improvement is achieved in the performance of a semiconductor device. In a method of manufacturing the semiconductor device, in an n-type semiconductor substrate, a p-type well as a p-type semiconductor region forming a part of a photodiode is formed and a gate electrode of a transfer transistor is formed. Then, after an n-type well as an n-type semiconductor region forming the other part of the photodiode is formed, a microwave is applied to the semiconductor substrate to heat the semiconductor substrate. Thereafter, a drain region of the transfer transistor is formed.

The present invention provides a method of more efficiently producing a semiconductor epitaxial wafer, which can suppress metal contamination by achieving higher gettering capability.

A method of producing a semiconductor epitaxial wafer 100 according to the present invention includes a first step of irradiating a semiconductor wafer 10 with cluster ions 16 to form a modifying layer 18 formed from a constituent element of the cluster ions 16 in a surface portion 10A of the semiconductor wafer; and a second step of forming an epitaxial layer 20 on the modifying layer 18 of the semiconductor wafer 10.

An image sensor for high angular response discrimination is provided. A plurality of pixels comprises a phase detection autofocus (PDAF) pixel and an image capture pixel. Pixel sensors of the pixels are arranged in a semiconductor substrate. A grid structure is arranged over the semiconductor substrate, laterally surrounding color filters of the pixels. Microlenses of the pixels are arranged over the grid structure, and comprise a PDAF microlens of the PDAF pixel and an image capture microlens of the image capture pixel. The PDAF microlens comprises a larger optical power than the image capture microlens, or comprises a location or shape so a PDAF receiving surface of the PDAF pixel has an asymmetric profile. A method for manufacturing the image sensor is also provided.

An embodiment isolation structure includes a first passivation layer over a bottom surface and extending along sidewalls of a trench in a semiconductor substrate, wherein the first passivation layer includes a first dielectric material. The semiconductor device further includes a passivation oxide layer in the trench on the first passivation layer, wherein the passivation oxide layer includes an oxide of the first dielectric material and has a higher atomic percentage of oxygen than the first passivation layer, The semiconductor device further includes a second passivation layer in the trench on the passivation oxide layer, wherein the second passivation layer also includes the first dielectric material and has a lower atomic percentage of oxygen than the passivation oxide layer.

A photoelectric conversion panel includes a TFT, a photodiode, a first organic film formed on an upper layer from the photodiode, a bias line formed on an upper layer from the first organic film, a data line separated from the bias line, a second organic film covering the first organic film, the bias line, and the data line, and a first inorganic insulating film. Part of the second organic film is disposed between the bias line and the data line. The first inorganic insulating film covers the second organic film.