Abstract: Provided is an image sensor device. The image sensor device includes a substrate having a front side and a back side. The image sensor includes first and second radiation-detection devices that are disposed in the substrate. The first and second radiation-detection devices are operable to detect radiation waves that enter the substrate through the back side. The image sensor also includes an anti-reflective coating (ARC) layer. The ARC layer is disposed over the back side of the substrate. The ARC layer has first and second ridges that are disposed over the first and second radiation-detection devices, respectively. The first and second ridges each have a first refractive index value. The first and second ridges are separated by a substance having a second refractive index value that is less than the first refractive index value.

Abstract: A novel germanium (Ge) photodetector is disclosed, containing a stripe layer including Ge, a substrate supporting the stripe layer, and P and N regions, which are located inside the substrate and near opposite sides of the stripe. The stripe layer containing Ge for light absorption is operated in a slow-light mode by adding combinations of a gradual taper indent structure and a periodic indent structure to reduce light scatterings and to control light group velocity inside the stripe. Due to the slower light traveling velocity inside the stripe, the absorption coefficient of the stripe containing Ge is upgraded to be 1 to 2 orders of magnitude larger than that of a traditional bulk Ge at L band, and so the absorption coefficient reaches more than 1 dB/?m at the wavelength of 1600 nm.

Abstract: A solar cell includes polysilicon P-type and N-type doped regions on a backside of a substrate, such as a silicon wafer. A trench structure separates the P-type doped region from the N-type doped region. Each of the P-type and N-type doped regions may be formed over a thin dielectric layer. The trench structure may include a textured surface for increased solar radiation collection. Among other advantages, the resulting structure increases efficiency by providing isolation between adjacent P-type and N-type doped regions, thereby preventing recombination in a space charge region where the doped regions would have touched.

Abstract: An optical sensor, according to an embodiment of the present invention, includes a photodetector region and a plurality of slats over the photodetector region. In an embodiment, the slats are made up of a plurality of metal layers connected in a stacked configuration with a plurality of metal columns. The metal columns can be made of metal vias, metal contacts and/or metal plugs. In an embodiment, the slats are angled relative to a surface of the photodetector region, wherein the angling of the slats is achieved by the metal layers being laterally offset relative to one another and/or metal columns being laterally offset relative to one another. In an alternative embodiment, the slats are made of an opaque polymer material, such as an opaque photoresist.

Abstract: Embodiments relate to buried structures for silicon devices which can alter light paths and thereby form light traps. Embodiments of the lights traps can couple more light to a photosensitive surface of the device, rather than reflecting the light or absorbing it more deeply within the device, which can increase efficiency, improve device timing and provide other advantages appreciated by those skilled in the art.

Abstract: A waveguide is provided on which an electromagnetic wave impinges, the electromagnetic wave having a wavelength ? included in a given interval ?? of interest centered on a ?centr. The waveguide comprises a film defining a surface on a plane on which the electromagnetic waves are apt to impinge, having a thickness in a direction substantially perpendicular to the surface, the film being realized in a material having a first refractive index; a plurality of scatterers being randomly distributed in two directions in at least a portion of the surface of the film, the scatterers having a substantially constant cross section along said substantially perpendicular direction. The scatterers are realized in a material having a second refractive index lower than the first refractive index, wherein the wavelength of the incident electromagnetic waves is comprised between 0.

Abstract: An organic light emitting display device includes a substrate having a luminescent region and a non-luminescent region, an insulation layer on the substrate, a first electrode on the insulation layer, at least one light emitting structure on the first electrode, a second electrode on the light emitting structure, and at least one reflecting structure at one of the first electrode or the second electrode around the at least one light emitting structure. The reflecting structure may be configured to reflect light back toward the luminescent region.

Abstract: Methods and structures for providing single-color or multi-color photo-detectors leveraging plasmon resonance for performance benefits. In one example, a radiation detector includes a semiconductor absorber layer having a first electrical conductivity type and an energy bandgap responsive to radiation in a first spectral region, a semiconductor collector layer coupled to the absorber layer and having a second electrical conductivity type, and a plasmonic resonator coupled to the collector layer and having a periodic structure including a plurality of features arranged in a regularly repeating pattern.

Abstract: A method of manufacturing a semiconductor light-receiving element includes: forming a semiconductor layer structure having a one-conductivity-type semiconductor layer having a first conduction type located on a side of light incidence, an opposite-conductivity-type semiconductor layer having a second conduction type opposite to the first conduction type, and a light-absorbing layer between the one-conductivity-type semiconductor layer and the opposite-conductivity type semiconductor layer, the opposite-conductivity-type semiconductor layer having a structure in which a first semiconductor layer comprised of a binary mixed crystal, a second semiconductor layer comprised of a three-or-more-element mixed crystal, and a third semiconductor layer comprised of a three-or-more-element mixed crystal having an energy gap smaller than that of the second semiconductor layer are laminated in this order from the light incidence side; forming a metal film that is in contact with the third semiconductor layer; and performin

Abstract: A solid-state imaging device includes a photoelectric conversion film which is interposed between two transparent electrodes outside a semiconductor substrate, wherein a film surface of the photoelectric conversion film is provided so as to incline with respect to a front surface of the semiconductor substrate.

Abstract: The invention relates to a semiconductor apparatus and a method of fabrication for a semiconductor apparatus, whereby the semiconductor apparatus includes a semiconductor layer and a passivation layer arranged on a surface of the semiconductor layer and serving for passivating the semiconductor layer surface, whereby the passivation layer comprises a chemically passivating passivation sublayer and a field-effect-passivating passivation sublayer, which are arranged one above the other on the semiconductor layer surface.

Abstract: Embodiments relate to buried structures for silicon devices which can alter light paths and thereby form light traps. Embodiments of the lights traps can couple more light to a photosensitive surface of the device, rather than reflecting the light or absorbing it more deeply within the device, which can increase efficiency, improve device timing and provide other advantages appreciated by those skilled in the art.

Abstract: An image sensor for low light cameras including a plurality of image pixels, each including: a photodiode layer; an oxide layer; a metal layer; a first microlens layer for focusing an incident light onto the photodiode layer; and a second microlens layer formed on top of the first microlens layer for generating a collimated light from a sharp-angled light from a low light camera and illuminating said collimated light to the first microlens layer to be focused on the photodiode layer.

Abstract: A photodiode device including a photosensitive diffusion junction within a single layer. The photodiode device further includes a resonant grating located within the single layer. The photosensitive diffusion junction is located within the resonant grating.

Abstract: A solid-state imaging device includes: photoelectric conversion units disposed in the form of matrix in an imaging region and a peripheral region around the imaging region; transfer electrodes provided on a side of the photoelectric conversion units arranged in the vertical direction of the matrix; and first-layer wirings and second-layer wirings in a multi-layer wiring structure disposed to connect the transfer electrodes in the horizontal direction of the matrix, wherein the first-layer wirings and the second-layer wirings are provided as light-shielding patterns for covering the photoelectric conversion units in the peripheral region.

Abstract: A method for manufacturing a solar cell includes performing a dry etching process to form a textured surface including a plurality of minute protrusions on a first surface of a semiconductor substrate, performing a first cleansing process for removing damaged portions of surfaces of the minute protrusions using a basic chemical and removing impurities adsorbed on the surfaces of the minute protrusions, performing a second cleansing process for removing impurities remaining or again adsorbed on the surfaces of the minute protrusions using an acid chemical after performing the first cleansing process, and forming an emitter region at the first surface of the semiconductor substrate.

Abstract: The present invention provides an organic display device, comprising: an organic solar module for obtaining solar energy and converting the obtained solar energy into electric power, and an ultraviolet organic light emitting module driven to emit ultraviolet light by the electric power obtained from the organic solar module. The present invention can fully use solar energy and carry out ultraviolet display by combining the ultraviolet organic light emitting module with the organic solar module.

Abstract: One of disclosed embodiments provides a photoelectric conversion device, comprising a member including a first surface configured to receive light, and a second surface opposite to the first surface, and a plurality of photoelectric conversion portions aligned inside the member in a depth direction from the first surface, wherein at least one of the plurality of photoelectric conversion portions other than the photoelectric conversion portion positioned closest to the first surface includes, on a boundary surface thereof with the member, unevenness having a difference in level larger than a difference in level of unevenness of the photoelectric conversion portion positioned closest to the first surface, and wherein the boundary surface having the unevenness is configured to localize or resonate light incident on the member from a side of the first surface around the boundary surface having the unevenness.

Abstract: At least one exemplary embodiment is directed to a solid state image sensor including at least one antireflective layer and/or non rectangular shaped wiring layer cross section to reduce dark currents and 1/f noise.

Abstract: A bipolar solar cell includes a backside junction formed by an N-type silicon substrate and a P-type polysilicon emitter formed on the backside of the solar cell. An antireflection layer may be formed on a textured front surface of the silicon substrate. A negative polarity metal contact on the front side of the solar cell makes an electrical connection to the substrate, while a positive polarity metal contact on the backside of the solar cell makes an electrical connection to the polysilicon emitter. An external electrical circuit may be connected to the negative and positive metal contacts to be powered by the solar cell. The positive polarity metal contact may form an infrared reflecting layer with an underlying dielectric layer for increased solar radiation collection.

Abstract: Structures and design structures for improved adhesion of protective layers of imager microlens structures are disclosed. A method of fabricating a semiconductor structure includes forming an interfacial region between a microlens and a protective oxide layer. The interfacial region has a lower concentration of oxygen than the protective oxide layer.

Abstract: A thin film photovoltaic device comprising a relief textured transparent cover plate, a layer of transparent conductive oxide having a layer thickness of less than 700 nm, a light absorbing active layer and a reflective back electrode, where the layer of transparent conductive oxide is a non-textured layer.

Abstract: Described are embodiments of apparatuses and systems including photonic devices having a conductive shunt layer, and methods for making such apparatuses and systems. A photonic device may include a device substrate, a photo-active region disposed on a first region of the device substrate, an isolation region in the device substrate, a contact disposed on a second region of the substrate such that the isolation region is located between the contact and the photo-active region, and a conductive material overlying the isolation region to shunt the first region with the second region. Other embodiments may be described and/or claimed.

Abstract: The present invention provides a wavelength conversion-type photovoltaic cell sealing material, the sealing material including at least one light emitting layer containing a group of spherical phosphors, the group of spherical phosphors having a ratio of a median value D50 of the group of spherical phosphors to a total thickness t of the light emitting layer of from 0.1 to 1.0, where the median value D50 is a median value of a volume particle size distribution of the group of spherical phosphors, and an integrated value N of a number particle size distribution from D25 to D75 of the group of spherical phosphors being 5% or more, when D25 is a particle size value at 25% of an integrated value of the volume particle size distribution of the group of spherical phosphors and D75 is a particle size value at 75% of the integrated value of the volume particle size distribution of the group of spherical phosphors; and a photovoltaic cell module including the sealing material.

Abstract: A solar cell element is disclosed. The solar cell element comprises a semiconductor substrate, a first electrode, a second electrode, a first wiring member and a second wiring member. The semiconductor substrate with a first surface and a second surface comprises a plurality of through-holes. The first electrode comprises a plurality of conduction portions and at least one first output extracting portion. The second electrode has a resistivity of less than 2.5×10-8 ?m (ohm-meter). The first wiring member comprises a first end face in a long direction thereof. The second wiring member comprises a second end face in a long direction thereof facing the first end face.

Abstract: A light receiving element includes a core configured to propagate a signal light, a first semiconductor layer having a first conductivity type, the first semiconductor layer being configured to receive the signal light from the core along a first direction in which the core extends, an absorbing layer configured to absorb the signal light received by the first semiconductor layer, and a second semiconductor layer having a second conductivity type opposite to the first conductivity type.

Abstract: A process is provided for contacting a nanostructured surface. In that process, a substrate is provided having a nanostructured material on a surface, the substrate being conductive and the nanostructured material being coated with an insulating material. A portion of the nanostructured material is at least partially removed. A conductor is deposited on the substrate in such a way that it is in electrical contact with the substrate through the area where the nanostructured material has been at least partially removed.

Abstract: A solid-state imaging device includes: a light-receiving element; and a multilayer film which is disposed on a side of a light-receiving surface of the light-receiving element and is formed by laminating a plurality of layers made of materials having different refractive indices, in which a defect layer is included in at least one of the laminated layers, wherein in the defect layer, a plurality of kinds of materials having different refractive indices coexist in a surface parallel to the light-receiving surface.

Abstract: A photovoltaic device includes a substrate, a transparent conductive oxide, an n-type window layer, a p-type absorber layer and an electron reflector layer. The electron reflector layer may include zinc telluride doped with copper telluride, zinc telluride alloyed with copper telluride, or a bilayer of multiple layers containing zinc, copper, cadmium and tellurium in various compositions. A process for manufacturing a photovoltaic device includes forming a layer over a substrate by at least one of sputtering, evaporation deposition, CVD, chemical bath deposition process, and vapor transport deposition process. The process includes forming an electron reflector layer over a p-type absorber layer.

Abstract: Methods and structures of barrier detectors are described. The structure may include an absorber that is at least partially reticulated. The at least partially reticulated absorber may also include an integrated electricity conductivity structure. The structure may include at least two contact regions isolated from one another. The structure may further include a barrier layer disposed between the absorber and at least two contact regions.

Abstract: An apparatus comprising a high-temperature photovoltaic transducer that is disposed between a source of light and another modality of solar energy conversion such that both the high-temperature photovoltaic transducer and the another modality of solar energy conversion generate electricity using a same source of light.

Abstract: Provided are a light emitting device and a method of manufacturing the same. A light emitting device includes an active layer; a first conductive semiconductor layer on the active layer; a second conductive semiconductor layer on the active layer so that the active layer is disposed between the first and second conductive semiconductor layers; and a photonic crystal structure comprising a first light extraction pattern on the first conductive semiconductor layer having a first period, and second light extraction pattern on the first conductive semiconductor layer having a second period, the first period being greater than ?/n, and the second period being identical to or smaller than ?/n, where n is a refractive index of the first conductive semiconductor layer, and ? is a wavelength of light emitted from the active layer.

Abstract: An imaging device includes an image sensor that includes a first group of pixels and a second group of pixels disposed on a semiconductor die. The first group of pixels are arranged to capture a first image and the second group of pixels are arranged to capture a second image. The imaging device also includes a first lens configured to focus image light from a first focus distance onto the first group of pixels. The imaging device further includes a second lens configured to focus the image light from a second focus distance onto the second group of pixels and not the first group of pixels. The first lens is positioned to focus the image light from the first focus distance onto the first group of pixels and not the second group of pixels. The first focus distance is different than the second focus distance.

Abstract: An image sensor having a wave guide includes a semiconductor substrate formed with a photodiode and a peripheral circuit region; an anti-reflective layer formed on the semiconductor substrate; an insulation layer formed on the anti-reflective layer; a wiring layer formed on the insulation layer and connected to the semiconductor substrate; at least one interlayer dielectric stacked on the wiring layer; and a wave guide connected to the insulation layer by passing through the interlayer dielectric and the wiring layer which are formed over the photodiode.

Abstract: A solid-state image pickup device includes an element isolation insulating film electrically isolating pixels on the surface of a well region; a first isolation diffusion layer electrically isolating the pixels under the element isolation insulating film; and a second isolation diffusion layer electrically isolating the pixels under the first isolation diffusion layer, wherein a charge accumulation region is disposed in the well region surrounded by the first and second isolation diffusion layers, the inner peripheral part of the first isolation diffusion layer forms a projecting region, an impurity having a conductivity type of the first isolation diffusion layer and an impurity having a conductivity type of the charge accumulation region are mixed in the projecting region, and a part of the charge accumulation region between the charge accumulation region and the second isolation diffusion layer is abutted or close to the second isolation diffusion layer under the projecting region.

Abstract: Apparatuses capable of and techniques for detecting long wavelength radiation are provided.

Abstract: A light emitting diode includes a semiconductor body including an active region that produces radiation, a carrier body fastened to the semiconductor body on an upper side of the semiconductor body, the carrier body including a luminescence conversion material consisting of a ceramic luminescence conversion material, a mirror layer applied to the semiconductor body on an underside of the semiconductor body remote from the upper side, and two contact layers, a first contact layer of the contact layers connected electrically conductively to an n-conducting region of the semiconductor body and a second contact layer of the contact layers connected electrically conductively to a p-conducting region of the semiconductor body.

Abstract: Disclosed is a flexible radiation detector including a substrate, a switching device on the substrate, an energy conversion layer on the switching device, a top electrode layer on the energy conversion layer, a first phosphor layer on the top electrode layer, and a second phosphor layer under the substrate.

Abstract: This photodetector capable of detecting electromagnetic radiation comprises: a doped semiconductor absorption layer for said radiation, capable of converting said radiation into charge carriers; a reflective layer that reflects the incident radiation that is not absorbed by semiconductor layer towards the latter, located underneath semiconductor layer; and a metallic structure placed on semiconductor layer that forms, with semiconductor layer, a surface Plasmon resonator so as to concentrate the incident electromagnetic radiation on metallic structure in the field concentration zones of semiconductor layer. Semiconductor zones for collecting charge carriers that are oppositely doped to the doping of semiconductor layer are formed in said semiconductor layer and have a topology that complements that of the field concentration zones.

Abstract: A solid state imaging device includes a photoelectric conversion portion in which the shape of potential is provided such that charge is mainly accumulated in a vertical direction.

Abstract: Avalanche photodiodes (APDs) having at least one top stressor layer disposed on a germanium (Ge)-containing absorption layer are described herein. The top stressor layer can increase the tensile strain of the Ge-containing absorption layer, thus extending the absorption of APDs to longer wavelengths beyond 1550 nm. In one embodiment, the top stressor layer has a four-layer structure, including an amorphous silicon (Si) layer disposed on the Ge-containing absorption layer; a first silicon dioxide (SiO2) layer disposed on the amorphous Si layer, a silicon nitride (SiN) layer disposed on the first SiO2 layer, and a second SiO2 layer disposed on the SiN layer. The Ge-containing absorption layer can be further doped by p-type dopants. The doping concentration of p-type dopants is controlled such that a graded doping profile is formed within the Ge-containing absorption layer to decrease the dark currents in APDs.

Abstract: Optically sensitive devices include a device comprising a first contact and a second contact, each having a work function, and an optically sensitive material between the first contact and the second contact. The optically sensitive material comprises a p-type semiconductor, and the optically sensitive material has a work function. Circuitry applies a bias voltage between the first contact and the second contact. The optically sensitive material has an electron lifetime that is greater than the electron transit time from the first contact to the second contact when the bias is applied between the first contact and the second contact. The first contact provides injection of electrons and blocking the extraction of holes. The interface between the first contact and the optically sensitive material provides a surface recombination velocity less than 1 cm/s.

Abstract: Novel laser processed semiconductor materials, systems, and methods associated with the manufacture and use of such materials are provided. In one aspect, for example, a method of processing a semiconductor material can include providing a semiconductor material and irradiating a target region of the semiconductor material with a beam of laser radiation to form a laser treated region. The laser radiation is irradiated at an angle of incidence relative to the semiconductor material surface normal of from about 5° to about 89°, and the laser radiation can be at least substantially p-polarized.

Abstract: Capacitance between a detection capacitor and a reset transistor is the largest among the capacitances between the detection capacitor and transistors placed around the detection capacitor. In order to reduce this capacitance, it is effective to reduce the channel width of the reset transistor. It is possible to reduce the effective channel width by distributing, in the vicinity of the channel of the reset transistor and the boundary line between an active region and an element isolation region, ions which enhance the generation of carriers of an opposite polarity to the channel.

Abstract: A solar cell includes polysilicon P-type and N-type doped regions on a backside of a substrate, such as a silicon wafer. A trench structure separates the P-type doped region from the N-type doped region. Each of the P-type and N-type doped regions may be formed over a thin dielectric layer. The trench structure may include a textured surface for increased solar radiation collection. Among other advantages, the resulting structure increases efficiency by providing isolation between adjacent P-type and N-type doped regions, thereby preventing recombination in a space charge region where the doped regions would have touched.

Abstract: A method and apparatus used for forming a lens and spacer combination, and imager module employing the spacer and lens combination. The apparatus includes a mold having a base, spacer section, and mold feature. The method includes using the mold with a blank to create a spacer that includes an integral lens. The spacer and lens combination and imager modules can be formed on a wafer level.

Abstract: A light-absorbing device and method employ a series of photon-absorbing semiconductor substructures. A first semiconductor substructure provides first and second energy states. A difference between the first and second states being such as to cause an electron to be promoted from the first state to the second state upon absorption of a photon of a first energy. A second semiconductor substructure provides third and fourth energy states. The third state is arranged to receive the electron from the second state. A difference between the third and fourth states being such as to cause the electron to be promoted from the third state to the fourth state upon absorption of a subsequent photon of a second energy. The third state has a lower energy than the second state, such as to cause the electron to dissipate energy as it passes from the second state to the third state.

Abstract: An avalanche photodiode according to the inventive concept includes a substrate, light absorption layers on the substrate, clad layers on the light absorption layers, and active regions in the clad layers. The light absorption layers, the clad layers, and the active regions constitute unit cells. Each of the unit cells has a fan-shape.

Abstract: This photodetector comprises a doped semiconductor layer; a reflective layer located underneath semiconductor layer; a metallic structure placed on semiconductor layer that forms, with semiconductor layer, a surface plasmon resonator, a plurality of semiconductor zones formed in semiconductor layer and oppositely doped to the doping of the semiconductor layer; and for each semiconductor zone, a conductor that passes through the photodetector from reflective layer to at least semiconductor zone and is electrically insulated from metallic structure, with semiconductor zone associated with corresponding conductor thus determining an elementary detection surface of the photodetector.

Abstract: Active or functional additives are embedded into surfaces of host materials for use as components in a variety of electronic or optoelectronic devices, including solar devices, smart windows, displays, and so forth. Resulting surface-embedded device components provide improved performance, as well as cost benefits arising from their compositions and manufacturing processes.