Abstract: A solid-state image capture device including: at least one photoelectric converter at an image capture surface of a substrate; at least one on-chip lens at the image capture surface of the substrate and above a light-receiving surface of the photoelectric converter; and an antireflection layer on an upper surface of the on-chip lens. The antireflection layer contains a binder resin having a lower refractive index than that of the on-chip lens and low-refractive-index particles having a lower refractive index than that of the binder resin.

Abstract: A method of making an optical member including high refractive index layers and low refractive index layers, which are each relatively thin as compared with an optical length, and disposed alternately in the lateral direction with respect to an optical axis. Each width of the high refractive index layers and the low refractive index layers is equal to or smaller than the wavelength order of incident light.

Abstract: A solar cell module includes first and second solar cells disposed adjacent to each other, and diffuse reflection wiring material including a front surface in which a textured diffuse-reflection portion for diffusely reflecting light is formed and a back surface, the back surface being connected to a front surface side of the first solar cell, the front surface being connected to one of aback surface of the second solar cell and an intermediate wiring material. A part of the diffuse-reflection portion corresponding to a first connection area where the diffuse reflection wiring material is connected to the one of the second solar cell and an intermediate wiring material has not texture or has a smaller height of the texture in a thickness direction than a part of the diffuse-reflection portion corresponding to a second connection area where the diffuse reflection wiring material to the first solar cell.

Abstract: The present application disclosed various embodiments of improved performance optically coated semiconductor devices and various methods for the manufacture thereof and includes depositing a first layer of a low density, low index of refraction material on a surface of a semiconductor device, depositing a multi-layer optical coating comprising alternating layers of low density, low index of refraction materials and high density, high index of refraction materials on the coated surface of the semi-conductor device, selectively ablating a portion of the alternating multi-layer optical coating to expose at least a portion of the low density first layer, and selectively ablating a portion of the first layer of low density material to expose at least a portion of the semiconductor device.

Abstract: In accordance with certain embodiments, arrays of phosphor dots are formed and associated with arrays of light-emitting elements to form lighting systems.

Abstract: A method of fabricating a differential doped solar cell is provided. The method comprises the steps of (a) providing a light doped semiconductor substrate; (b) forming a heavy doped layer having the same type of dopant used in step (a) on a front surface of the semiconductor substrate; and (c) forming an emitter layer having a different type of dopant used in step (a) on a surface of the heavy doped layer to constitute a p-n junction with the heavy doped layer.

Abstract: Magnetically adjusting color-converting particles within a matrix and associated devices, systems, and methods are disclosed herein. A magnetic-adjustment process can include applying a magnetic field to a mixture including a non-solid matrix and a plurality of color-converting particles (e.g. magnetically anisotropic color-converting particles). The magnetic field can cause the plurality of color-converting particles to move into a generally non-random alignment (e.g., a generally non-random magnetic alignment and/or a generally non-random shape alignment) within the non-solid matrix. The non-solid matrix then can be solidified to form a solid matrix. A magnetic-adjustment process can be performed in conjunction with testing and/or product binning of solid-state radiation transducer devices.

Abstract: The purpose of the present invention is to provide a method for disposing a photoelectric conversion element accurately on the focal point of a condenser lens. The method of the present invention comprises a step of forming a focal point on the reverse surface of the condenser lens to be a hydrophilic region, a step of removing the remained photoresist to obtain the condenser lens having the reverse surface where the hydrophilic region is surrounded by a water-repellent region formed of the fluoroalkylsilane film and a step of disposing the photoelectric conversion element on the hydrophilic region to obtain the solar cell comprising the condenser lens and the photoelectric conversion element.

Abstract: An image pickup apparatus includes: an image pickup device disposed in a first principal surface of a silicon substrate, the image pickup device sensing infrared light; an electrode pad disposed on the first principal surface; a front-face wiring connecting the image pickup device and the electrode pad; an external connection terminal disposed on a second principal surface of the silicon substrate; a back-face wiring connecting the electrode pad and the external connection terminal via a substrate through-hole extending from the second principal surface side through the silicon substrate to a back face of the electrode pad; and a light blocking layer disposed on the second principal surface, the light blocking layer covering a trench portion surrounding the image pickup device and a region surrounded by the trench portion.

Abstract: According to one embodiment, an image detector comprises a plurality of photosensitive detector unit cells interconnected to a plurality of integrated circuits by a plurality of direct bond interconnects. Each unit cell includes an absorber layer and a separation layer. The absorber layer absorbs incident photons such that the absorbed photons excite photocurrent comprising first charged carriers and second charged carriers having opposite polarities. The separation layer separates the first charged carriers for collection at one or more first contacts and the second charged carriers for collection at one or more second contacts. The first and second contacts include the direct bond interconnects to conduct the first charged carriers and the second charged carriers from the unit cells in order to facilitate image processing.

Abstract: A manufacturing method of a solid-state imaging device includes: preparing a photoelectric conversion device; forming an insulating layer on a surface of the photoelectric conversion device; forming a wire-grid polarizer on a support base; bonding a forming surface of the wire-grid polarizer on the support base to the insulating layer on the surface of the photoelectric conversion device and removing the support base from the wire-grid polarizer.

Abstract: A solid-state imaging apparatus and a manufacturing method of a solid-state imaging apparatus are provided. Metal wirings 102 and 103 are formed in an effective pixel region A and out-of effective pixel region B of a semiconductor substrate 100, and an etch stop layer 118 is formed over the metal wirings 102 and 103. Moreover, an insulating film 119 is formed on the etch stop layer 118, and another metal wiring 104 is formed on the insulating film 119 in the out-of effective pixel region B. Next, the insulating film 119 in the effective pixel region A is removed by using the etch stop layer 118, and interlayer lenses 105 are formed in the step in the effective pixel region A where the insulating film 119 is removed.

Abstract: The present invention provides a photodetector which solves the problem of low sensitivity of a photodetector, an optical communication device equipped with the same, and a method for making the photodetector, and a method for making the optical communication device. The photodetector includes a substrate, a lower cladding layer arranged on the substrate, an optical waveguide arranged on the lower cladding layer, an intermediate layer arranged on the optical waveguide, a optical absorption layer arranged on the intermediate layer, a pair of electrodes arranged on the optical absorption layer, and wherein the optical absorption layer includes a IV-group or III-V-group single-crystal semiconductor, and the optical absorption layer absorbs an optical signal propagating through the optical waveguide.

Abstract: There is provided a solar cell comprising: a substrate; a rear electrode layer disposed on the substrate; a light absorption layer disposed on the rear electrode layer; and a window layer disposed on the light absorption layer, wherein the window layer includes a plurality of conductive particles. The conductive particles improve the optical and electrical properties of the window layer.

Abstract: Systems, methods and apparatus are provided for electromechanical systems devices having a sidewall spacer along at least one sidewall of a conductive line. An electromechanical systems device can include a sidewall spacer along at least one sidewall of a conductive line under a movable layer. The sidewall spacer can be sloped such that the sidewall spacer has a decreasing width away from a substrate under the movable layer. The conductive line can be configured to route an electrical signal to the electromechanical systems device. In some implementations, a black mask structure of an electromechanical systems device can include the conductive line.

Abstract: The monolithic application of a high speed TWPDA with impedance matching. Use of the high speed monolithic TWPDA will allow for more efficient transfer of optical signals within analog circuits and over distances.

Abstract: According to one embodiment, a method of manufacturing a back-illuminated solid-state imaging device including forming a mask with apertures corresponding to a pixel pattern on the surface of a semiconductor layer, implanting second-conductivity-type impurity ions into the semiconductor layer from the front side of the layer to form second-conductivity-type photoelectric conversion parts and forming a part where no ion has been implanted into a pixel separation region, forming at the surface of the semiconductor layer a signal scanning circuit for reading light signals obtained at the photoelectric conversion parts after removing the mask, and removing the semiconductor substrate and a buried insulating layer from the semiconductor layer after causing a support substrate to adhere to the front side of the semiconductor layer.

Abstract: An integrated die-level camera system and method of making the camera system include a first die-level camera formed at least partially in a die. A second die level camera is also formed at least partially in the die. Baffling is formed to block stray light between the first and second die-level cameras.

Abstract: The first face of the pad is situated between the front-side face of the second semiconductor substrate and a hypothetical plane including and being parallel to the front-side face, and a second face of the pad that is a face on the opposite side of the first face is situated between the first face and the front-side face of the second semiconductor substrate, and wherein the second face is connected to the wiring structure so that the pad is electrically connected to the circuit arranged in the front-side face of the second semiconductor substrate via the wiring structure.

Abstract: A microcavity-controlled two-dimensional carbon lattice structure device selectively modifies to reflect or to transmit, or emits, or absorbs, electromagnetic radiation depending on the wavelength of the electromagnetic radiation. The microcavity-controlled two-dimensional carbon lattice structure device employs a graphene layer or at least one carbon nanotube located within an optical center of a microcavity defined by a pair of partial mirrors that partially reflect electromagnetic radiation. The spacing between the mirror determines the efficiency of elastic and inelastic scattering of electromagnetic radiation inside the microcavity, and hence, determines a resonance wavelength of electronic radiation that is coupled to the microcavity. The resonance wavelength is tunable by selecting the dimensional and material parameters of the microcavity. The process for manufacturing this device is compatible with standard complementary metal oxide semiconductor (CMOS) manufacturing processes.

Abstract: A method for fabricating an image sensor is provided. A substrate is provided, and then a plurality of photoresist patterns is formed on the substrate. The photoresist patterns are arranged in a first array and defined by a plurality of photomask patterns arranged as a photomask pattern array, wherein a top view of each photoresist pattern has a substantially square shape and a distance between two neighboring photoresist patterns decreases from a center of the first array toward an edge of the first array. Besides, each photomask pattern includes a transparent portion and an opaque portion, wherein an area proportion of the transparent portion included in a photomask pattern increases from the center toward the edge of the photomask pattern array. Then, a thermal reflow step is performed to convert the photoresist patterns into a plurality of microlenses arranged in a second array.

Abstract: Disclosed herein is a method of manufacturing a solid-state image pickup element having a lens provided above a light receiving portion. The manufacturing method includes: forming a lens base material layer composing the lens; forming an intermediate film having a thermal expansion coefficient larger than that of a resist on the lens base material layer; forming the resist in contact with the intermediate film; forming the resist into a lens shape by thermal reflow; and transferring the lens shape of the resist to the lens base material layer by etching, thereby forming the lens.

Abstract: Described herein is a contact for a photovoltaic device and method of making the same. The contact has a transparent conductive oxide stack, where a first portion of the transparent conductive oxide stack is formed by atmospheric pressure vapor deposition and a second portion of the transparent conductive oxide stack is formed by physical vapor deposition.

Abstract: A method of manufacturing a semiconductor device is provided. The method includes providing a transparent substrate having predefined active regions and non-active regions. Thereafter, the method includes spraying droplets of a lacquer on the predefined active regions to form corresponding lacquer layer regions, such that the non-active regions do not have presence of the lacquer. The lacquer layer regions are of a predefined thickness to enable their functional texturing. Texturing of lacquer layer enables light trapping or light extraction. Thereafter, one or more semiconductor layers are deposited o the lacquer layer regions and a cover substrate is provided. The cover substrate is joined to the transparent substrate at a portion of the non-active regions and encapsulates the lacquer layer regions and the one or more semiconductor layers between itself and the transparent substrate.

Abstract: Disclosed is a method for manufacturing a photovoltaic device including: a forming the first sub-layer including impurity by allowing first flow rate values of the source gas introduced into one group of a first group consisting of odd numbered process chambers and a second group consisting of even numbered process chambers to be maintained constant in each of the process chambers of the one group; and a forming the second sub-layer including impurity by allowing second flow rate values of the source gas introduced into the other group of the first group and the second group to be maintained constant in each of the process chambers of the other group, wherein the second flow rate values are less than the first flow rate values.

Abstract: A back side illumination image sensor reduced in chip size has a capacitor disposed in a vertical upper portion of a pixel region in the back side illumination image sensor in which light is illuminated from a back side of a subscriber, thereby reducing a chip size, and a method for manufacturing the back side illumination image sensor. The capacitor of the back side illumination image sensor reduced in chip size is formed in the vertical upper portion of the pixel region, not in the outside of a pixel region, so that the outside area of the pixel region for forming the capacitor is not required, thereby reducing a chip size.

Abstract: A solid state imaging device having a back-illuminated type structure in which a lens is formed on the back side of a silicon layer with a light-receiving sensor portion being formed thereon. Insulating layers are buried into the silicon layer around an image pickup region, with the insulating layer being buried around a contact layer that connects an electrode layer of a pad portion and an interconnection layer of the surface side. A method of manufacturing such a solid-state imaging device is also provided.

Abstract: Certain embodiments provide a solid-state imaging device including a semiconductor substrate, a reflector, and an external electrode. The semiconductor substrate has a photosensitive region including a photodiode on the surface thereof and the back surface thereof is polished by mirror finish. The reflector is formed on the back surface of the semiconductor substrate and reflects infrared rays incident on the photosensitive region. The external electrode is electrically connected to the photosensitive region.

Abstract: Back reflector arrays are applied to the surface distal to the incident light receiving surface of a thin film solar cell to increase its efficiency by altering the reflected light path and thereby increasing the path length of light through the active layer of the solar cell. The back reflector is an array of features of micrometer proportions. The feature may be concave or convex features such as hemispheres, hemi-ellipsoids, partial-spheres, partial-ellipsoids, or combinations thereof The feature may be pyramidal. A method of forming the back reflector array is by forming an array of features from a photocurable resin, subsequent curing the resin and metalizing the cured resin to render the surface reflective. The photocurable resin can be applied by inkjet printing or rolling or stamping with a mold.

Abstract: A semiconductor device includes a microlens provided in a pixel area and a monitoring structure provided in a peripheral area that is separate from the pixel area. The monitoring structure has a shape correlated with a shape of the microlens. A shape of a section of the monitoring structure in a plane perpendicular to a substrate is constant.

Abstract: In certain embodiments, an apparatus for down-converting and detecting photons includes a detector layer and a nanocrystal layer. The nanocrystal layer includes nanocrystals operable to absorb first photons of a higher energy and emit second photons of a lower energy in response to the absorption. The detector layer is configured to detect the second photons. In certain embodiments, a method for manufacturing an apparatus for down-converting and detecting photons includes preparing an outer surface of a substrate. Nanocrystals are disposed outwardly from the outer surface. The nanocrystals are operable to absorb first photons of a higher energy and emit second photons of a lower energy in response to the absorption.

Abstract: A radiation-sensitive detector includes a photosensor layer with one or more photosensor dixels and a composite scintillator layer with one or more scintillator dixels optically coupled to the photosensor layer. The composite scintillator layer is formed from a mixture including a scintillator material having a first refractive index corresponding to a first wavelength and a photo-resist used in micro-electromechanical systems production, having a second refractive index corresponding to the first wavelength. The first and second refractive indices are substantially matched, and the composite scintillator layer produces light having the first wavelength and that is indicative of x-radiation detected thereby.

Abstract: A means of forming unevenness for preventing specular reflection of a pixel electrode, without increasing the number of process steps, is provided. In a method of manufacturing a reflecting type liquid crystal display device, the formation of unevenness (having a radius of curvature r in a convex portion) in the surface of a pixel electrode is performed by the same photomask as that used for forming a channel etch type TFT, in which the convex portion is formed in order to provide unevenness to the surface of the pixel electrode and give light scattering characteristics.

Abstract: A photovoltaic device including a rear electrode which may also function as a rear reflector. In certain example embodiments of this invention, the rear electrode includes a metallic based reflective film that is oxidation graded, so as to be more oxided closer to a rear substrate (e.g., glass substrate) supporting the electrode than at a location further from the rear substrate. In other words, the rear electrode is oxidation graded so as to be less oxided closer to a semiconductor absorber of the photovoltaic device than at a location further from the semiconductor absorber in certain example embodiments. In certain example embodiments, the interior surface of the rear substrate may optionally be textured so that the rear electrode deposited thereon is also textured so as to provide desirable electrical and reflective characteristics. In certain example embodiments, the rear electrode may be of or include Mo and/or MoOx, and may be sputter-deposited using a combination of MoOx and Mo sputtering targets.

Abstract: A method for manufacturing a solid state image forming device according to an embodiment includes forming a transparent resin layer 20 on a semiconductor substrate 11, having a plurality of photodiode layers 12 formed thereon in a lattice, through R, G, and B color filters that are formed according to a Bayer arrangement; forming a plurality of first microlens mother dies 23 on the transparent resin layer 20 at the positions corresponding to the green color filters G in such a manner that the outer peripheries thereof are separated from each other; forming a plurality of second microlens mother dies 24 in such a manner that they are formed to fill the gap between the first microlens mother dies 23 and the outer peripheries thereof are separated from each other; and etching the transparent resin layer 20 with the plurality of first microlens mother dies 23 and the plurality of second microlens mother dies 24 being used as masks.

Abstract: A solid-state imaging device includes: a first lens layer; and a second lens layer, wherein the second lens layer is formed at least at a periphery of each first microlens formed based on the first lens layer, and the second lens layer present at a central portion of each of the first microlenses is thinner than the second lens layer present at the periphery of the first microlens or no second lens layer is present at the central portion of each of the first microlenses.

Abstract: An imaging device includes a silicon substrate having a photoelectric conversion element therein, and a wiring layer on a front-surface side of the silicon substrate. The photoelectric conversion element performs photoelectric conversion on light which enters the photoelectric conversion element from the front-surface side through the wiring layer, and performs photoelectric conversion on light which enters the photoelectric conversion element from a back-surface side of the silicon substrate without going through the wiring layer.

Abstract: Spectral modification devices and methods are described. For example, an apparatus for spectral modification of incident radiation includes a substrate and Raman shifting material embedded in or on the substrate, the Raman shifting material selected based on a desired optical or electrical performance of a light absorbing structure.

Abstract: An organic light emitting diode (OLED) display device and a method of fabricating the same are provided. The OLED display device includes a substrate having a thin film transistor region and a capacitor region, a buffer layer disposed on the substrate, a gate insulating layer disposed on the substrate, a lower capacitor electrode disposed on the gate insulating layer in the capacitor region, an interlayer insulating layer disposed on the substrate, and an upper capacitor electrode disposed on the interlayer insulating layer and facing the lower capacitor electrode, wherein regions of each of the buffer layer, the gate insulating layer, the interlayer insulating layer, the lower capacitor electrode, and the upper capacitor electrode have surfaces in which protrusions having the same shape as grain boundaries of the semiconductor layer are formed. The resultant capacitor has an increased surface area, and therefore, an increased capacitance.

Abstract: The present invention provides a solid-state imaging device comprising: a semiconductor substrate having a pixel region and a peripheral circuit region; a multilayer wiring layer including layers of wiring and an interlayer film interposed therebetween, and disposed above the semiconductor substrate to cover the pixel region and the peripheral circuit region except areas above the photoelectric conversion elements; a waveguide member filling the areas above the photoelectric conversion elements (waveguides) and covering the multilayer wiring layer at least within the pixel region; and an optical structure (composed of a color filter material and a lens material) disposed above the waveguide member within the pixel region, wherein a groove is formed by removing a portion of the waveguide member from an area within the pixel region that is in a border between the pixel region and the peripheral circuit region.

Abstract: To improve the use efficiency of materials and provide a technique of fabricating a display device by a simple process. The method includes the steps of providing a mask on a conductive layer, forming an insulating film over the conductive layer provided with the mask, removing the mask to form an insulating layer having an opening; and forming a conductive film in the opening so as to be in contact with the exposed conductive layer, whereby the conductive layer and the conductive film can be electrically connected through the insulating layer. The shape of the opening reflects the shape of the mask. A mask having a columnar shape (e.g., a prism, a cylinder, or a triangular prism), a needle shape, or the like can be used.

Abstract: A method of fabricating a flexible photovoltaic film cell with an iron diffusion barrier layer. The method includes: providing a foil substrate including iron; forming an iron diffusion barrier layer on the foil substrate, where the iron diffusion barrier layer prevents the iron from diffusing; forming an electrode layer on the iron diffusion barrier layer; and forming at least one light absorber layer on the electrode layer. A flexible photovoltaic film cell is also provided, which cell includes: a foil substrate including iron; an iron diffusion barrier layer formed on the foil substrate to prevent the iron from diffusing; an electrode layer formed on the iron diffusion barrier layer; and at least one light absorber layer formed on the electrode layer.

Abstract: The invention provides highly fluorescent materials comprising a single (n=0) or a series (n=1, 2, etc.) of benzo heterocyclic systems. The photo-stable highly luminescent chromophores are useful in various applications, including in wavelength conversion films. Wavelength conversion films have the potential to significantly enhance the solar harvesting efficiency of photovoltaic or solar cell devices.

Abstract: Present embodiments include a bandage sensor having an electrically conductive adhesive transfer tape layer as a Faraday shield. The electrically conductive transfer tape layer may be used in lieu of a fully metallic Faraday shield. The present embodiments also include a sensor cable having one or more conductive polymer EMI/RFI shields in place of a fully metallic EMI/RFI shield. Methods for manufacturing and remanufacturing such sensors and cables are also disclosed.

Abstract: A method for manufacturing thin film solar cells, includes forming a light permeable first electrode layer in the back light surface of a glass substrate, and formed in the first electrode layer a plurality of first openings for exposing a part of the back light surface therefrom; forming a photoelectric conversion layer on the first electrode layer and the exposed back light surface, and forming a plurality of second openings in the photoelectric conversion layer for exposing a part of the first electrode layer therefrom; and forming a glistening second electrode layer having a plurality of third openings formed therein, wherein the second electrode layer comprises a conductive colloid comprised of non-diffractive fillings and polymeric base material.

Abstract: According to one embodiment, a solid state imaging device includes a sensor substrate having a plurality of pixels formed on an upper face, a microlens array substrate having a plurality of microlenses formed and a connection post with one end bonded to a region between the microlenses on the microlens array substrate and with the other end bonded to the upper face.

Abstract: A method for generating electric power including the steps of: (a) preparing a solar cell having a condensing lens and a solar cell element, wherein the solar cell element includes an n-type GaAs layer, a p-type GaAs layer, a quantum tunneling layer, an n-type InGaP layer, a p-type InGaP layer, a p-type window layer, an n-side electrode, and a p-side electrode, and satisfies the following equation (I): d2<d1, d3<d1, nanometer?d2?4 nanometers, 1 nanometer?d3?4 nanometers, d5<d4, d6<d4, 1 nanometer?d5?5 nanometers, 1 nanometer?d6?5 nanometers, 100 nanometers?w2, 100 nanometers?w3, 100 nanometers?w4, and 100 nanometers?w5. . . (I); and (b) irradiating a region S which is included in the surface of the p-type window layer through the condensing lens with light to satisfy the following equation (II) in order to generate a potential difference between the n-side electrode and the p-side electrode: w6?w1. . . (II).

Abstract: A light-emitting device is provided with a substrate decomposition prevention layer using as a matrix at least one selected from the group consisting of boron nitride (B—N), silicon carbide (Si—C), and silicon carbon nitride (Si—C—N), and patterned into a predetermined shape; an n-type nitride clad layer formed on the substrate decomposition prevention layer; a nitride active layer formed on the n-type nitride clad layer; a p-type nitride clad layer formed on the nitride active layer; a p-type ohmic contact layer formed on the p-type nitride clad layer; a p-type electrode pad formed on the p-type ohmic contact layer; an n-type ohmic contact layer electrically connected to the n-type nitride clad layer by means of a patterned region of the substrate decomposition prevention layer; and an n-type electrode pad formed beneath the n-type ohmic contact layer.

Abstract: According to one embodiment, a solid-state imaging device includes a semiconductor substrate of a first conductive type having a diffusion layer region provided on a surface thereof, a diffusion layer of the first conductive type for a pixel separation whose bottom portion is formed at the deepest position of the diffusion layer region in a pixel region, and a first deep diffusion layer of the first conductive type provided at the deepest position of the diffusion layer region in a first peripheral logic region for electrically connecting the semiconductor substrate and the first peripheral logic region and having a first concentration gradient equal to that of the diffusion layer for pixel separation.

Abstract: Some embodiments include photonic systems. The systems may include a silicon-containing waveguide configured to direct light along a path, and a detector proximate the silicon-containing waveguide. The detector may comprise a detector material which has a lower region and an upper region, with the lower region having a higher concentration of defects than the upper region. The detector material may comprise germanium in some embodiments. Some embodiments include methods of forming photonic systems.