Abstract: An image sensor has photodiodes formed in a Si substrate and configured to prevent carriers generated at a deep position of the Si substrate from affecting adjacent photodiodes due to lateral diffusion (crosstalk between pixels). A modified layer is formed between adjacent photodiodes and at a depth below that of the photodiodes by a laser to generate a recombination level to thereby suppress crosstalk between pixels.

Abstract: An integrated circuit structure includes a semiconductor substrate, an image sensor extending from a front surface of the semiconductor substrate into the semiconductor substrate, and an isolation structure extending from a back surface of the semiconductor substrate into the semiconductor substrate, wherein the isolation structure includes an air-gap therein. An air-gap sealing layer is on a backside of the semiconductor substrate. The air-gap sealing layer seals the air-gap, wherein the air-gap sealing layer includes a portion exposed to the air-gap.

Abstract: A substrate and a delamination film are separated by a physical means, or a mechanical means in a state where a metal film formed over a substrate, and a delamination layer comprising an oxide film including the metal and a film comprising silicon, which is formed over the metal film, are provided. Specifically, a TFT obtained by forming an oxide layer including the metal over a metal film; crystallizing the oxide layer by heat treatment; and performing delamination in a layer of the oxide layer or at both of the interface of the oxide layer is formed.

Abstract: A method for producing a solid-state imaging element which has photoconversion pixels, the method including forming an impurity region of the first conduction type and a second impurity region of the second conduction type on the impurity region of the first conduction type by ion implantation by using the same mask; forming on the surface of the semiconductor substrate a transfer gate constituting the charge transfer section which extends over the second impurity region of the second conduction type; forming a charge accumulating region of the first conduction type constituting the sensor section by ion implantation; and forming a first impurity region of the second conduction type, which has a higher impurity concentration than the second impurity region of the second conduction type, by ion implantation.

Abstract: A resistance memory device and a memory apparatus and data processing apparatus having the same are provided. The resistance memory device includes a pair of electrode layers and a variable resistance layer interposed between the pair of electrode layers. The variable resistance layer includes at least one variable resistance material layer and a piezoelectric material layer coupled to the at least one variable resistance material layer.

Abstract: A photoelectric conversion apparatus includes a semiconductor substrate on which a photoelectric conversion element and a transistor are arranged and a plurality of wiring layers including a first wiring layer and a second wiring layer above the first wiring layer, in which a connection between the semiconductor substrate and any of the plurality of wiring layers, between a gate electrode of the transistor and any of the plurality of wiring layers, or between the first wiring layer and the second wiring layer, has a stacked contact structure.

Abstract: A method of manufacturing a solid-state image sensor having a first charge accumulation region, a second charge accumulation region, includes implanting ions into a semiconductor substrate through first and second openings of a mask to form the first and second charge accumulation regions. The implanting ions includes a first implantation of implanting ions into a portion below a first transfer gate, and a second implantation of implanting ions into a portion below a second transfer gate in a direction different from a direction of the first implantation.

Abstract: A method of fabricating an image sensor device includes forming an insulating layer on a substrate including a photodiode therein, and forming a wiring structure on the insulating layer. The wiring structure includes at least one wiring layer and at least one insulating interlayer. A cavity is formed extending into the wiring structure over the photodiode to expose a surface of the at least one insulating interlayer. The surface of the at least one insulating interlayer exposed by the cavity is modified to define a hydrophobic surface. Related systems and devices are also discussed.

Abstract: A method for reducing stripe patterns comprising receiving scattered light signals from a backside surface of a laser annealed backside illuminated image sensor wafer, generating a backside surface image based upon the scattered light signals, determining a distance between an edge of a sensor array of the laser anneal backside illuminated image sensor wafer and an adjacent boundary of a laser beam and re-calibrating the laser beam if the distance is less than a predetermined value.

Abstract: According to embodiments of the present invention, a semiconductor photomultiplier device is provided. The semiconductor photomultiplier device includes a substrate having a front side and a back side, a common electrode of a first conductivity type adjacent to the back side, and a cell including an active region of a second conductivity type adjacent to the front side, and a contact region of the second conductivity type adjacent to the front side, the contact region being spaced apart from the active region by a separation region.

Abstract: One embodiment relates to a connector that includes a diode. The diode has an anode and a cathode. The connector further includes a first electrical connection which connects to the anode, a second electrical connection which also connects to the anode, and a third electrical connection which connects to the cathode. Another embodiment relates to a photovoltaic laminate which includes a string of photovoltaic cells and three electrical conductors extending out of two discrete penetrations of the laminate. A first electrical conductor is connected to a first end of the string, a second electrical conductor is connected to a second end of the string, and a third electrical conductor is also connected to the second end of the string. The first and third electrical conductors extend out of the first discrete penetration, while the second electrical conductor extends out of the second discrete penetration. Other features and embodiments are also disclosed.

Abstract: A manufacturing method for a photoelectric conversion apparatus in which a microlens is arranged for multiple electric charge accumulation regions formed on a semiconductor substrate, includes forming a first impurity region of a first conductive type on the semiconductor substrate; and forming a second impurity region of a second conductive type that is opposite the first conductive type in a part of the first impurity region to isolate the first impurity region into multiple regions such that each of the multiple electric charge accumulation regions includes isolated first impurity regions.

Abstract: An image sensor includes a substrate including a pixel array region and a logic region where a surface of the pixel array region is higher than a surface of the logic region, and a light shielding pattern formed over the substrate of the logic region and having a surface on substantially the same plane as a surface of the substrate.

Abstract: Embodiments of mechanisms for forming an image-sensor device are provided. The image-sensor device includes a substrate having a front surface and a back surface. The image-sensor device also includes a radiation-sensing region formed in the substrate. The radiation-sensing region is operable to detect incident radiation that enters the substrate through the back surface. The radiation-sensing region further includes an epitaxial isolation feature formed in the substrate and adjacent to the radiation-sensing region. The radiation-sensing region and the epitaxial isolation feature have different doping polarities.

Abstract: Image sensors are provided. In the image sensor, an area of a device isolation layer may be reduced and elements may be isolated from each other by a channel stop region extending between the photoelectric conversion region and the device isolation layer, such that a dark current property of the image sensor may be improved.

Abstract: Pixel electrodes have end portions inclined at inclination angles ?, where 30°???85°, relative to a substrate surface of a substrate. An organic layer disposed on the pixel electrodes is formed by vapor deposition using deposition beams that enter the substrate surface at incident angles ? smaller than 90°??max, where ?max is the maximum inclination angle among the inclination angles of the end portions of the pixel electrodes, under a deposition substrate temperature condition lower than the glass transition temperature of the organic layer.

Abstract: A method of forming of an image sensor device includes a patterned hardmask layer is formed over a substrate. The patterned hard mask layer has a plurality of first openings in a periphery region, and a plurality of second openings in a pixel region. A first patterned mask layer is formed over the pixel region to expose the periphery region. A plurality of first trenches is etched into the substrate in the periphery region. Each first trench, each first opening and each second opening are filled with a dielectric material. A second patterned mask layer is formed over the periphery region to expose the pixel region. The dielectric material in each second opening over the pixel region is removed. A plurality of dopants is implanted through each second opening to form various doped isolation features in the pixel region.

Abstract: BSI image sensors and methods. In an embodiment, a substrate is provided having a sensor array and a periphery region and having a front side and a back side surface; a bottom anti-reflective coating (BARC) is formed over the back side to a first thickness, over the sensor array region and the periphery region; forming a first dielectric layer over the BARC; a metal shield is formed; selectively removing the metal shield from over the sensor array region; selectively removing the first dielectric layer from over the sensor array region, wherein a portion of the first thickness of the BARC is also removed and a remainder of the first thickness of the BARC remains during the process of selectively removing the first dielectric layer; forming a second dielectric layer over the remainder of the BARC and over the metal shield; and forming a passivation layer over the second dielectric layer.

Abstract: An embodiment of a die comprising: a semiconductor body including a front side, a back side, and a lateral surface; an electronic device, formed in said semiconductor body and including an active area facing the front side; a vertical conductive connection, extending through the semiconductor body and defining a conductive path between the front side and the back side of the semiconductor body; and a conductive contact, defining a conductive path on the front side of the semiconductor body, between the active area and the vertical conductive connection, wherein the vertical conductive connection is formed on the lateral surface of the die, outside the active area.

Abstract: There is provided a solid state imaging device according to the embodiment. The solid state imaging device includes an imaging area and an element isolation unit having a light shielding effect. In the imaging area, a plurality of photoelectric conversion elements is two-dimensionally arranged in a matrix in a semiconductor layer. The element isolation unit is embedded so as to surround a light-receiving region of each photoelectric conversion element. A center position of an opening region surrounding the light-receiving region is positioned on the center side of the imaging area than a corresponding center position of the light-receiving region.

Abstract: The present invention is directed toward a detector structure, detector arrays, and a method of detecting incident radiation. The present invention comprises a photodiode array and method of manufacturing a photodiode array that provides for reduced radiation damage susceptibility, decreased affects of crosstalk, reduced dark current (current leakage) and increased flexibility in application.

Abstract: A semiconductor device includes a carrier substrate having at least one conductor track, at least one converter element structured at least partly from a further semiconductor substrate, and conductive structures formed on a respective converter element. The at least one converter element is electrically linked to the at least one conductor track via at least one at least partly conductive supporting element arranged between a contact side of the carrier substrate and an inner side of the converter element. The inner side is oriented toward the carrier substrate. The at least one converter element is arranged on the contact side of the carrier substrate such that the inner side of the converter element is kept spaced apart from the contact side of the carrier substrate. The at least one converter element and the conductive structures formed thereon are completely embedded into at least one insulating material.

Abstract: A method of manufacturing a backside illuminated image sensor, including forming a first isolation layer in a first semiconductor layer, such that the first isolation layer defines pixels of a pixel array in the first semiconductor layer, forming a second semiconductor layer on a first surface of the first semiconductor layer, forming a second isolation layer in the second semiconductor layer, such that the second isolation layer defines active device regions in the second semiconductor layer, forming photo detectors and circuit devices by implanting impurities into a first surface of the second semiconductor layer, the first surface of the second semiconductor layer facing away from the first semiconductor layer, forming a wiring layer on the first surface of the second semiconductor layer, and forming a light filter layer on a second surface of the first semiconductor layer.

Abstract: The present invention improves the performance of an image sensor. In a planar view, fluorine is introduced into a part overlapping with a channel region in a gate electrode GE1 of an amplification transistor and is not introduced into the interior of a semiconductor substrate 1S. Concretely as shown in FIG. 20, a resist film FR1 is patterned in the manner of opening the part planarly overlapping with the channel region in the gate electrode GE1. Then fluorine is injected into the interior of the gate electrode GE1 exposed from an opening OP1 by an ion implantation method using the resist film FR1 in which the opening OP1 is formed as a mask.

Abstract: Embodiments of the present disclosure include an image sensor device and methods of forming the same. An embodiment is an image sensor device including a first plurality of pickup regions in a photosensor array area of a substrate, each of first plurality of pickup regions having a first width and a first length, a second plurality of pickup regions in a periphery area of the substrate, the periphery area along at least one side of the photosensor array area, each of second plurality of pickup regions having a second width and a second length.

Abstract: Provided is a solid-state imaging device including: a photodiode which converts an optical signal to signal charges; a transfer gate which transfers the signal charges from the photodiode; an impurity diffusion layer to which the signal charges are transferred by the transfer gate; and a MOS transistor of which a gate is connected to the impurity diffusion layer. The impurity diffusion layer has a first conduction type semiconductor layer and a second conduction type semiconductor layer which is formed in the first conduction type semiconductor layer and under an end portion of the transfer gate.

Abstract: A solar cell module manufacturing apparatus includes a stage, a holding member, a moving mechanism, and a pushing member. The stage suctions a plurality of elongated solar cells that is arranged to form a solar cell module. The holding member releasably holds a portion of a solar cell to be placed on the stage. The moving mechanism moves the holding member forward and backward with respect to the stage. The moving mechanism moves the holding member backward in a state that an end portion in a front side of the cell held by the holding member that has been moved forward is suctioned on the stage, and then the portion of the cell is released by the holding member. The pushing member moves over the cell such that the pushing member pushes a lift portion of the cell down to the stage while the holding member moves backward.

Abstract: A multilayer back electrode for a photovoltaic thin-film solar cell, including: at least one bulk back electrode layer, at least one, ohmic, contact layer, obtained by applying at least one ply containing/essentially made of at least one metal chalcogenide, selected from molybdenum, tungsten, tantalum, cobalt, and/or niobium, and the chalcogen being selected from selenium and/or sulfur, with physical or chemical gas phase deposition while using at least one metal chalcogenide source, or obtained by applying at least one metal ply (first ply), the first ply and the bulk back electrode layer not corresponding in their composition, in the particular metal used or, if multiple metals are in the metal ply and the bulk back electrode layer, with regard to at least one, in particular all of these metals (Mo, W, Ta, Nb, and/or Co) and a metal chalcogenide ply (second ply), use of the back electrode for manufacturing thin-film solar cells and modules, photovoltaic thin-film solar cells and modules containing the back

Abstract: A device includes a plurality of isolation spacers, and a plurality of bottom electrodes, wherein adjacent ones of the plurality of bottom electrodes are insulated from each other by respective ones of the plurality of isolation spacers. A plurality of photoelectrical conversion regions overlaps the plurality of bottom electrodes, wherein adjacent ones of the plurality of photoelectrical conversion regions are insulated from each other by respective ones of the plurality of isolation spacers. A top electrode overlies the plurality of photoelectrical conversion regions and the plurality of isolation spacers.

Abstract: A solid-state image pickup device includes: an organic photoelectric conversion layer; a passivation layer formed to cover a top of the organic photoelectric conversion layer; and an insulating film formed on the passivation layer and in a slit produced on a level difference in the passivation layer, the insulating film having a smaller refractive index than that of the passivation layer.

Abstract: A single crystal silicon layer is formed on a principal surface of a first wafer by epitaxial growth. A silicon oxide layer is formed on the single crystal silicon layer. Next, a defect layer is formed inside the single crystal silicon layer by ion implantation, and then, the second wafer is bonded to the silicon oxide layer on the first wafer. After that, an SOI wafer including the silicon oxide layer formed on the second wafer and the single crystal silicon layer formed on the silicon oxide layer is formed by separating the first wafer including the single crystal silicon layer from the second wafer including the single crystal silicon layer in the defect layer. Then, a photodiode is formed in the single crystal silicon layer. An interconnect layer is formed on a surface of the single crystal silicon layer which is opposite to the silicon oxide layer.

Abstract: Disclosed is an apparatus and method for manufacturing a thin film type solar cell, which enables the enhancement of productivity, the apparatus for manufacturing a thin film type solar cell including a first electrode forming unit; a first separation part; an optoelectric conversion layer forming unit; a contact line forming unit; a printing unit; and an etching process unit, wherein the etching process unit removes the optoelectric conversion layer in a second separation part to expose the first electrode in the second separation part through a wet etching process.

Abstract: A method for module-level processing of photovoltaic cells is provided. The method includes: bonding at least one crystalline silicon photovoltaic substrate to a carrier by means of an adhesive layer, thereby leaving part of the adhesive layer uncovered; after bonding, exposing the uncovered part of the adhesive layer and the at least one crystalline silicon photovoltaic substrate to a plasma; and removing a surface portion of the at least one crystalline photovoltaic substrate. The method may further include performing an annealing step of the adhesive before bonding the at least one photovoltaic substrate to the carrier, and performing an outgassing step of the adhesive after bonding the at least one photovoltaic substrate to the carrier. The method may further include module-level rear side processing of the at least one crystalline silicon photovoltaic substrate to make a photovoltaic module.

Abstract: A device having a plurality of thin film photovoltaic cells (PV) formed over a passivation layer. The device comprises a plurality of thin film photovoltaic (PV) cells formed over the passivation layer, each PV cell includes at least a lower conducting layer (LCL) and an upper conducting layer (UCL); and a conducting path connecting at least a UCL of a first PV cell to at least a LCL of a second PV cell, wherein at least a first array of PV cells comprised of at least a first portion of the plurality of PV cells is connected by the respective UCL and LCL of each PV cell to provide a first voltage output. In an embodiment the passivation layer is formed over a target integrated circuit (TIC), the TIC having a top surface and a bottom surface.

Abstract: A method of fabricating both a multijunction solar cell and an inverted metamorphic multijunction solar cell in a single process using a MOCVD reactor by forming a first multijunction solar cell on a semiconductor substrate; forming a release layer over the first solar cell; forming an inverted metamorphic second solar cell over the release layer; and etching the release layer so as to separate the multijunction first solar cell and the inverted metamorphic second solar cell.

Abstract: Provided is an image pickup device, including: a first trench provided between a plurality of pixels in a light-receiving region of a semiconductor substrate, the semiconductor substrate including the light-receiving region and a peripheral region, the light-receiving region being provided with the plurality of pixels each including a photoelectric conversion section; and a second trench provided in the peripheral region of the semiconductor substrate, wherein the semiconductor substrate has a variation in thickness between a portion where the first trench is provided and a portion where the second trench is provided.

Abstract: Disclosed herein is a solid-state imaging element including: a transfer section configured to transfer charge generated simultaneously by a photoelectric conversion section in all pixels to a memory section and have a metal gate; and a light-shielding section formed by filling a metal into a groove portion formed by digging an interlayer insulating film around the transfer section.

Abstract: An image pickup element includes: a semiconductor substrate including a photoelectric conversion section for each pixel; a pixel separation groove provided in the semiconductor substrate; and a fixed charge film provided on a light-receiving surface side of the semiconductor substrate, wherein the fixed charge film includes a first insulating film and a second insulating film, the first insulating film being provided contiguously from the light-receiving surface to a wall surface and a bottom surface of the pixel separation groove, and the second insulating film being provided on a part of the first insulating film, the part corresponding to at least the light-receiving surface.

Abstract: An image sensor including a pixel array, each pixel including, in a substrate of a doped semiconductor material of a first conductivity type, a first doped region of a second conductivity type at the surface of the substrate; an insulating trench surrounding the first region; a second doped region of the first conductivity type, more heavily doped than the substrate, at the surface of the substrate and surrounding the trench; a third doped region of the second conductivity type, forming with the substrate a photodiode junction, extending in depth into the substrate under the first and second regions and being connected to the first region; and a fourth region, more lightly doped than the second and third regions, interposed between the second and third regions and in contact with the first region and/or with the third region.

Abstract: The method of manufacturing a light absorbing layer for a solar cell by performing thermal treatment on a specimen configured to include thin films of one or more of copper, indium, and gallium on a substrate and element selenium, includes steps of: (a) heating a wall of a chamber up to a predefined thin film formation temperature in order to maintain a selenium vapor pressure; (b) mounting the specimen and the element selenium on the susceptor at the room temperature and loading the susceptor in the chamber; and (c) heating the specimen in the lower portion of the susceptor and, at the same time, heating the element selenium in the upper portion of the susceptor, wherein, in the step (c), in order for liquefied selenium not to be condensed on the specimen which is loaded at the room temperature and is not yet heated, the temperature of the element selenium and the specimen loaded in the chamber are individually controlled, so that the selenium vapor pressure of an inner space of the chamber does not exceed a

Abstract: A photodiode array PDA1 is provided with a substrate S wherein a plurality of photodetecting channels CH have an n-type semiconductor layer 32. The photodiode array PDA1 is provided with a p? type semiconductor layer 33 formed on the n-type semiconductor layer 32, resistors 24 provided for the respective photodetecting channels CH and each having one end portion connected to a signal conducting wire 23, and an n-type separating portion 40 formed between the plurality of photodetecting channels CH. The p? type semiconductor layer 33 forms pn junctions at an interface to the n-type semiconductor layer 32 and has a plurality of multiplication regions AM for avalanche multiplication of carriers generated with incidence of detection target light, corresponding to the respective photodetecting channels. An irregular asperity 10 is formed in a surface of the n-type semiconductor layer 32 and the surface is optically exposed.

Abstract: Method for manufacturing a microelectronic device from a first substrate (10), including the production of at least one electronic component in the semi-conductor substrate after transferring the first substrate (10) onto a second substrate (20), characterized in that it comprises: a first phase carried out prior to the transfer, and including forming at least one pattern made of a sacrificial material in a layer of the first substrate (10), a second phase carried out after the transfer and including the substitution of the electronic component for the pattern.

Abstract: A solar cell module is provided with: a plurality of solar cells, each of which comprises a first electrode and a second electrode that are formed on a photoelectric conversion unit; and a wiring material that is fitted on the first electrode and the second electrode using an adhesive and connects the solar cells with each other. The adhesive is provided so as to extend beyond a region (R) directly below the wiring material and to adhere to a lateral surface of the wiring material. The solar cell module has a pore in the region (R) directly below the wiring material.

Abstract: A production device (2) and a method for forming multilayered (3, 4, 5, 6, 7) modules, in particular solar modules (1), which have at least one translucent sheet-like layer (3, 6) and at least one solar- or light-active element is provided. The production device (2) forms the layer structure and has an applicator (33) for a connecting layer (5, 7) for the aforementioned layers (3, 4, 6). Furthermore, the device has a controllable curve(arch)-forming device (17) for bending and rolling a sheet-like layer (3, 6) while the layers are being applied.

Abstract: A method includes forming a blocking layer over a substrate, and etching the blocking layer to form a trench in the blocking layer. A dielectric layer is formed, wherein the dielectric layer comprises a first portion over the blocking layer, and a second portion in the trench. After the step of forming the dielectric layer, an implantation is performed to implant an impurity into the substrate to form a deep well region. After the implantation, the dielectric layer and the blocking layer are removed.

Abstract: In a conventional imaging device, a light-blocking member for blocking incident luminous fluxes is provided for each pixel, for generating a parallax image. However, the light-blocking member is provided apart from the photoelectric converter element, and so unnecessary light such as diffracted light generated at the boundary between the light-blocking member and the aperture portion sometimes reaches the photoelectric converter element. In view of this, provided is an imaging sensor including: photoelectric converter elements aligned two dimensionally, and photoelectric converting incident light into an electric signal; and reflection rate adjusted films, each of which is formed on a light receiving surface of a photoelectric converter element of at least a part of the photoelectric converter elements and at least includes a first portion having a first reflection rate and a second portion having a second reflection rate different from the first reflection rate.

Abstract: A solid-state imaging apparatus includes a plurality of phase difference detection pixels configured adjacent to one another; and an isolation structure arranged so as to isolate light entering each of light-receiving units of the plurality of phase difference detection pixels, in which the isolation structure is formed so as to have a inclined side wall surface whose cross section is tapered.

Abstract: A method of fabricating organic solar panels with transparent contacts. The method uses a layer-by-layer spray technique to create the anode layer. The method includes placing the substrate on a flat magnet, aligning a magnetic shadow mask over the substrate, applying photoresist to the substrate using spray photolithography, etching the substrate, cleaning the substrate, spin coating a tuning layer on substrate, spin coating an active layer of P3HT/PCBM on the substrate, spray coating the substrate with a modified PEDOT solution, and annealing the substrate.

Abstract: According to one embodiment, a solid-state imaging device includes a photodiode includes an N-type region and a P-type region, a floating diffusion region, and a transfer transistor. The N-type diffusion region of the photodiode comprises a first semiconductor region and a second semiconductor region formed shallower than the first semiconductor region. An end portion of the first semiconductor region is positioned on the floating diffusion region side rather than an end portion of a gate electrode of the transfer transistor. An end portion of the second semiconductor region is set in substantially the same position as that of the end portion of the gate electrode of the transfer transistor.

Abstract: A structure and method of manufacture is disclosed for a backside thinned imager that incorporates a conformal, Al2O3, low thermal budget, surface passivation. This passivation approach facilitates fabrication of backside thinned, backside illuminated, silicon image sensors with thick silicon absorber layer patterned with vertical trenches that are formed by etching the exposed back surface of a backside-thinned image sensor to control photo-carrier diffusion and optical crosstalk. A method of manufacture employing conformal, Al2O3, surface passivation approach is shown to provide high quantum efficiency and low dark current while meeting the thermal budget constraints of a finished standard foundry-produced CMOS imager.