Abstract: A backside illuminated image sensor with an array of image sensor pixels is provided. Each image pixel may include a photodiode and associated pixel circuits formed in a front surface of a semiconductor substrate. Silicon inner microlenses may be formed on a back surface of the semiconductor substrate. In particular, positive inner microlenses may be formed over the photodiodes, whereas negative inner microlenses may be formed over the associated pixel circuits. Buried light shielding structures may be formed over the negative inner microlenses to prevent pixel circuitry that is formed in the substrate between two neighboring photodiodes from being exposed to incoming light. The buried light shielding structures may be lined with absorptive antireflective coating material to prevent light from being reflected off the surface of the buried light shielding structures.

Abstract: A back-illuminated silicon photodetector has a layer of Al2O3 deposited on a silicon oxide surface that receives electromagnetic radiation to be detected. The Al2O3 layer has an antireflection coating deposited thereon. The Al2O3 layer provides a chemically resistant separation layer between the silicon oxide surface and the antireflection coating. The Al2O3 layer is thin enough that it is optically innocuous. Under deep ultraviolet radiation, the silicon oxide layer and the antireflection coating do not interact chemically. In one embodiment, the silicon photodetector has a delta-doped layer near (within a few nanometers of) the silicon oxide surface. The Al2O3 layer is expected to provide similar protection for doped layers fabricated using other methods, such as MBE, ion implantation and CVD deposition.

Abstract: A method for manufacturing high efficiency solar cells is disclosed. The method comprises providing a thin dielectric layer and a doped polysilicon layer on the back side of a silicon substrate. Subsequently, a high quality oxide layer and a wide band gap doped semiconductor layer can both be formed on the back and front sides of the silicon substrate. A metallization process to plate metal fingers onto the doped polysilicon layer through contact openings can then be performed. The plated metal fingers can form a first metal gridline. A second metal gridline can be formed by directly plating metal to an emitter region on the back side of the silicon substrate, eliminating the need for contact openings for the second metal gridline. Among the advantages, the method for manufacture provides decreased thermal processes, decreased etching steps, increased efficiency and a simplified procedure for the manufacture of high efficiency solar cells.

Abstract: A photonic structure including a substrate of either crystalline silicon or germanium and a multilayer distributed Bragg reflector (DBR) positioned on the substrate. The DBR includes material substantially crystal lattice matching the DBR to the substrate. The DBR includes a plurality of pairs of layers of material including any combination of IV materials and any rare earth oxide (REO). A photonic device including multilayers of single crystal IV material positioned on the DBR and including material substantially crystal lattice matching the DBR to the photonic device.

Abstract: An imaging system may include an image sensor having backside illuminated near infrared image sensor pixels. Each pixel may be formed in a graded epitaxial substrate layer such as a graded n-type epitaxial layer. Each pixel may be separated from an adjacent pixel by an isolation trench formed in the graded epitaxial layer. The isolation trench may be a continuous isolation trench or may be formed from a combined front side isolation trench and backside isolation trench that are separated by a wall structure. A buried front side reflector may be provided that reflects light such as infrared light that has passed through a pixel back into the pixel, thereby effectively doubling the silicon absorption depth of the pixels.

Abstract: A front-side illuminated image sensor with an array of image sensor pixels is provided. Each image pixel may include a photodiode, transistor gate structures, shallow trench isolation structures, and other associated pixel circuits formed in a semiconductor substrate. Buried light shielding structures that are opaque to light may be formed over regions of the substrate to prevent the transistor gate structures, shallow trench isolation structures, and the other associated pixel circuits from being exposed to stray light. Buried light shielding structures formed in this way can help reduce optical pixel crosstalk.

Abstract: A reflective film including Ag of an Ag alloy is patterned in a uniform thickness without decreasing reflectivity. The reflective film is formed on the entire surface of a first insulating film by sputtering, vacuum deposition or the like, and a barrier metal film having a given pattern is formed on the reflective film by a lift-off method. The reflective film is wet etched using a silver etching liquid. The barrier metal film is not wet etched by the silver etching liquid, and therefore functions as a mask, and the reflective film in a region on which the barrier metal film has been formed remains not etched. As a result, the reflective film having a desired patter can uniformly be formed on the first insulating film.

Abstract: Provided is a solar cell, including: a semiconductor substrate having a p-n junction; an antireflection film formed on at least one side of the semiconductor substrate; first electrodes formed on the antireflection film; and second electrodes covering the first electrodes, wherein only the first electrodes selectively penetrate the antireflection film and is thus connected with the semiconductor substrate by a punch through process.

Abstract: Electrical contact to the front side of a photovoltaic cell is provided by an array of conductive through-substrate vias, and optionally, an array of conductive blocks located on the front side of the photovoltaic cell. A dielectric liner provides electrical isolation of each conductive through-substrate via from the semiconductor material of the photovoltaic cell. A dielectric layer on the backside of the photovoltaic cell is patterned to cover a contiguous region including all of the conductive through-substrate vias, while exposing a portion of the backside of the photovoltaic cell. A conductive material layer is deposited on the back surface of the photovoltaic cell, and is patterned to form a first conductive wiring structure that electrically connects the conductive through-substrate vias and a second conductive wiring structure that provides electrical connection to the backside of the photovoltaic cell.

Abstract: The present disclosure provides an image sensor semiconductor device. The semiconductor device includes a semiconductor substrate having a first type of dopant; a semiconductor layer having a second type of dopant different from the first type of dopant and disposed on the semiconductor substrate; and an image sensor formed in the semiconductor layer.

Abstract: A photovoltaic cell includes an absorbing layer configured to generate electron-hole pairs from incident photons of incoming light; and a first grating layer arranged at a first surface of the absorbing layer which is opposite to a second surface of the absorbing layer from which light is incident, wherein the first grating layer includes at least one grating extending along the first surface, wherein the at least one grating has grating structures which are dimensioned to provide a reflectivity for light incident through the absorbing layer back into the absorbing layer.

Abstract: A method for providing, on a carrier (40), an insulative spacer layer (26) which is patterned such that a cavity (27) is formed which enables connection of an optical semiconductor element (41) to the intended conductor structure (22) when placed inside the cavity (27). The cavity (27) is formed such that it, through its shape, extension and/or depth, accurately defines a location of an optical element (45; 61) in relation to the optical semiconductor element (41). Through the provision of such a patterned insulative spacer layer, compact and cost-efficient optical semiconductor devices can be mass-produced based on such a carrier without the need for prolonged development or acquisition of new and expensive manufacturing equipment.

Abstract: A high efficiency solar battery using a fluorescent substance to efficiently use incident light and thereby improve conversion efficiency. The solar battery of the present invention comprises: a front part including a front electrode and configured to receive light; a generating part disposed behind the front part to generate electricity from specific wavelengths of light incident through the front part; and a rear part disposed behind the generating part and comprising a rear electrode, wherein a first fluorescent substance is dispersed in the front part so as to absorb light having wavelengths different from the specific wavelengths, convert the absorbed light into light having the specific wavelengths, and output the converted light.

Abstract: A solar cell employs an optical fiber and semiconductor nanowires grown around the fiber. A p-n junction based design, organic-inorganic heterojunction, or a dye-sensitized structure is built at the surfaces of the nanowires. Light entering the fiber from a tip propagates through the fiber until it enters a nanowire where it reaches a photovoltaic element. Light entering the fiber cannot escape until it interacts with a photovoltaic element, thereby increasing the solar conversion efficiency. The fiber can transmit light, while the nanowires around the fibers increase the surface area of light exposure.

Abstract: A semiconductor device manufacturing method including a process of forming a silicon oxide film by thermally oxidizing silicon in the atmosphere of oxygen gas or in the atmosphere of mixed gas of oxygen and hydrogen at a temperature of 800° C. or more in the state in which at least the silicon surface serving as a light-receiving portion of a photodiode is exposed, and a process of depositing a silicon nitride film on the silicon oxide film. At least the silicon oxide film and the silicon nitride film are finally left on the surface of the photodiode as an antireflection film.

Abstract: A solar concentrator is described. The solar concentrator includes a plane including a plurality of concentrating elements, wherein each concentrating element includes a hollow taper including a first opening; and at least one photoelectric conversion layer covering inner side surfaces of the concentrating elements.

Abstract: Discussed herein are a solar cell and a fabricating method thereof. The solar cell includes a first conductivity-type semiconductor substrate, a second conductivity-type semiconductor layer formed on a front surface of the first conductivity-type semiconductor substrate, and having a conductivity opposite to that of the first conductivity-type semiconductor substrate, an anti-reflection film including at least one opening exposing a part of a surface of the second conductivity-type semiconductor layer, and formed on the second conductivity-type semiconductor layer, at least one front electrode contacting a part of the surface of the second conductivity-type semiconductor layer exposed through the at least one opening, and at least one rear electrode formed on a rear surface of the first conductivity-type semiconductor substrate, wherein the at least one front electrode includes a metal containing silver and lead-free glass frit.

Abstract: A method and structure for a solar cell forms and utilizes a low resistivity and high transmission semiconductor in a top and/or bottom layer (e.g., a top or bottom contact). Some embodiments relate to solar cells having a top or bottom transparent contact layer comprising doped cadmium oxide (CdO) or alloys of CdO.

Abstract: A solar cell structure includes stacked layers in reverse order on a germanium substrate. A heterostructure including an (In)GaAs absorbing layer and a disordered emitter layer is provided in the solar cell structures. Controlled spalling may be employed as part of the fabrication process for the solar cell structure, which may be single or multi-junction.

Abstract: Provided is a substrate for a thin-film photoelectric conversion device which makes it possible to produce the device having improved characteristics at low cost and high productivity. The substrate includes a transparent base member, with a transparent underlying layer and a transparent electrode layer successively stacked on one main surface of the transparent base member. The underlying layer includes transparent insulating fine particles and transparent binder, and the particles are dispersed to cover the one main surface with a coverage factor of particles ranging from 30% or more to less than 80%. An antireflection layer is provided on the other main surface of the transparent base. The antireflection layer includes transparent insulating fine particles and transparent binder, and the particles are dispersed to cover the other main surface with a coverage factor greater than the underlying layer. The transparent electrode layer contains zinc oxide deposited by low-pressure CVD method.

Abstract: A solar cell includes a substrate. The substrate has a light-receiving surface and a back surface opposite to the light-receiving surface. The substrate includes plural trenches formed on the back surface. The solar cell includes plural n-type diffusion areas and plural p-type diffusion areas alternately disposed on the back surface and the surface of the trenches. The possibility of recombination of the electron-hole pair while moving can be reduced because of the trenches, which are formed in the substrate.

Abstract: A method of fabricating a solar cell includes the following steps. At first, a substrate including a doped layer is provided. Subsequently, a patterned material layer partially overlapping the doped layer is formed on the substrate, and a first metal layer is conformally formed on the patterned material layer and the doped layer. Furthermore, a patterned mask layer totally overlapping the patterned material layer is formed on the first metal layer, and a second metal layer is formed on the doped layer not overlapped by the patterned material layer. Then, the patterned mask layer, the first metal layer between the patterned mask layer and the patterned material layer and a part of the patterned material layer are removed.

Abstract: A solar cell comprises an n-type semiconductor layer, a p-type semiconductor layer, a p-side electrode layer, an n-side electrode; and a ZnO transparent electrode layer. The n-side electrode layer consists of AgxAu1-x, and x represents a value of not less than 0.1 and not more than 0.5. The ZnO transparent electrode layer is composed of a plurality of ZnO columnar particles and each ZnO columnar particle has a longitudinal direction substantially parallel to a normal line of the ZnO transparent electrode layer. The cross-sectional area of each ZnO columnar particles that appears by cutting the ZnO columnar particles perpendicularly to the longitudinal direction increases from the upper surface of the n-side electrode layer to the upper surface of the ZnO transparent electrode layer.

Abstract: A photovoltaic cell with reduced shading and series resistance for increased efficiency. A contact grid containing a set of optical structures is embedded into a substrate. An array of electrical contacts is aligned and in electrical communication with the optical structures and provides electrical communication between the active layer and the substrate.

Abstract: In accordance with one embodiment, a digital X-ray detector is provided. The detector includes a scintillator layer configured to absorb radiation emitted from a radiation source and to emit optical photons in response to the absorbed radiation. The detector also includes a complementary metal-oxide-semiconductor (CMOS) light imager that is configured to absorb the optical photons emitted by the scintillator layer. The CMOS light imager includes a first surface and a second surface, and the first surface is disposed opposite the second surface. The scintillator layer contacts the first surface of the CMOS light imager.

Abstract: A method of fabricating a solar cell includes forming an emitter layer of a second conductive type on a front surface and a back surface of a substrate of a first conductive type opposite to the second conductive type, forming an anti-reflection layer on the front surface of the substrate, partially removing the anti-reflection layer and the emitter layer to form an isolation groove dividing the emitter layer into a plurality of regions, removing a portion of the emitter layer formed on the back surface of the substrate, and forming a passivation layer covering the isolation groove and the back surface of the substrate.

Abstract: A method of fabricating a solar cell is disclosed. The method includes the steps of forming a sacrificial layer on a silicon substrate, forming a doped silicon layer atop the sacrificial substrate, forming a silicon film atop the doped silicon layer, forming a plurality of interdigitated contacts on the silicon film, contacting each of the plurality of interdigitated contacts with a metal contact, and removing the sacrificial layer.

Abstract: Self-reducing metal inks and systems and methods for producing and using the same are disclosed. In an exemplary embodiment, a method may comprise selecting a metal-organic (MO) precursor, selecting a reducing agent, and dissolving the MO precursor and the reducing agent in an organic solvent to produce a metal ink that remains in a liquid phase at room temperature. Metal inks, including self-reducing and fire-through metal inks, are also disclosed, as are various applications of the metal inks.

Abstract: Disclosed is a method for manufacturing a photovoltaic device that includes: providing a substrate having a first electrode formed thereon; forming a first unit cell, the first unit cell including a first conductive silicon layer, an intrinsic silicon layer and a second conductive silicon layer, which are sequentially stacked from the first electrode; exposing to the air either a portion of an intermediate reflector formed on the first unit cell or the second conductive silicon layer of the first unit cell; forming the rest of the intermediate reflector or the entire intermediate reflector on the second conductive silicon layer of the first unit cell in a second manufacturing system; and forming a second unit cell on the intermediate reflector in the second manufacturing system, the second unit cell including a first conductive silicon layer, an intrinsic silicon layer and a second conductive silicon layer, sequentially stacked.

Abstract: A method of manufacturing a solar cell includes forming jagged portions non-uniformly on a surface of a substrate, forming a first type semiconductor and a second type semiconductor in the substrate, forming a first electrode to contact the first type semiconductor, and forming a second electrode to contact the second type semiconductor. An etchant used in a wet etching process in manufacturing the solar cell includes about 0.5 wt % to 10 wt % of HF, about 30 wt % to 60 wt % of HNO3, and up to about 30 wt % of acetic acid based on total weight of the etchant.

Abstract: In this method for producing a photoelectric conversion device: an i-type non-crystalline layer and an n-type non-crystalline layer comprising a non-crystalline semiconductor film are formed on the light-receiving surface of a semiconductor substrate; an i-type non-crystalline layer and an n-type non-crystalline layer comprising a non-crystalline semiconductor film are formed on the back surface of the semiconductor substrate; a protective layer is formed on the n-type non-crystalline layer; an insulating layer is formed on the n-type non-crystalline layer; and in the state where the top of the n-type non-crystalline layer is covered by the protective layer, patterning is performed by eliminating a portion of the i-type non-crystalline layer, the n-type non-crystalline layer, and the insulating layer.

Abstract: Provided are a solar cell and a method of fabricating the same. The solar cell includes: a substrate; a back electrode layer on the substrate; a light absorbing layer on the rear electrode layer; a window layer on the light absorbing layer; a plurality of beads in the light absorbing layer; and a trap layer on each surface of the plurality of beads.

Abstract: To provide a method of manufacturing at low cost a light emitting device that converts the wavelength of light radiated by a light emitting element and emits, the method includes: forming a phosphor layer on a translucent substrate; arranging a plurality of light emitting elements with a predetermined spacing, the light emitting elements having an electrode formed face provided with positive and negative electrodes respectively and arranged with the electrode formed faces on the top; embedding a resin containing phosphor particles so that an upper face of the embedded resin does not bulge over a plane containing the electrode formed faces; and curing the resin, and then cutting and dividing the cured resin, the phosphor layer and the translucent substrate into a plurality of light emitting devices each including one or more of the light emitting elements.

Abstract: Provided is a single junction type CIGS thin film solar cell, which includes a CIGS light absorption layer manufactured using a single junction. The single junction type CIGS thin film solar cell includes a substrate, a back contact deposited on the substrate, a light absorption layer deposited on the back contact and including a P type CIGS layer and an N type CIGS layer coupled to the P type CIGS layer using a single junction, and a reflection prevention film deposited on the light absorption layer.

Abstract: A solar cell and method for producing same is disclosed. The solar cell includes a multijunction solar cell structure and a notch filter designed to reflect solar energy that does not contribute to the current output of the multijunction solar cell. By reflecting unused solar energy, the notch filter allows the solar cell to run cooler (and thus more efficiently) yet it still allows all junctions to fully realize their electrical current production capability.

Abstract: A solar cell having on a light incident surface side an electrode with both low resistivity and high transparency to promote efficient excitation of carriers using inexpensive materials. The solar cell includes a photoelectric conversion layer, a first electrode layer arranged on the light incident surface side, and a second electrode layer arranged opposed to the first electrode layer. The first electrode layer has a thickness in the range of 10 to 200 nm, and plural penetrating openings, each of which occupies an area in the range of 80 nm2 to 0.8 ?m2, and has an aperture ratio in the range 10 to 66%. The first electrode layer can be produced by etching using an etching mask in the form of a single particle layer of fine particles, or of a dot pattern formed by self-assembly of a block copolymer, or of a stamper.

Abstract: The embodiment provides a package structure for a chip and a method for fabricating the same. The package structure for the chip includes a chip having a substrate and a bonding pad structure. The chip has an upper surface and a lower surface. An upper packaging layer covers the upper surface of the chip. A spacer layer is between the upper packaging layer and the chip. A conductive path is electrically connected to the bonding pad structure. An anti-reflective layer is disposed between the spacer layer and the upper packaging layer. An overlapping region is between the anti-reflective layer and the spacer layer.

Abstract: A photovoltaic device is described. The photovoltaic device comprises an organic-based antireflection layer. A method of making a photovoltaic device is also described.

Abstract: Multi-zone IR solar cell processing furnaces using a single, full-width conveyor belt; selected zones are divided into multiple lanes by upper or/and lower longitudinal divider walls, and heated by high intensity radiation IR lamps backed by a flat plate of ultra-high reflectance ceramic material. Lamp numbers and spacing in each zone/lane can be varied. Power to each lamp, or zone/lane lamp array, both upper and lower, is individually and independently controlled to provide infinite number of temperature profiles in each heating zone/lane. In multi-lane zones the IR lamps are folded, the inner ends being supported by the lane dividers. Lamp external power leads are both accessible from one side of the furnace. The lamp internal filaments include non-radiant and radiant sections arranged so that a pair of radiant sections are aligned in the lamp-folded configuration and disposed over the full width of the solar cell wafers.

Abstract: According to one embodiment, a method for manufacturing a semiconductor device includes implanting impurity ions to a semiconductor layer in which an electrode is embedded; forming a light absorption film which absorbs laser light at a side of the electrode to which the laser light is irradiated; and activating the impurity ions by irradiating laser light to the semiconductor layer at which the light absorption film is formed in the forming.

Abstract: A thin film solar cell according to the inventive concept includes a back side electrode on a substrate, a light absorption layer on the back side electrode, a buffer layer on the light absorption layer, a front side transparent electrode on the buffer layer, a grid electrode partially formed on the front side transparent electrode and exposing a top surface of a portion of the front side transparent electrode, and an anti-reflection layer covering the exposed top surface of the front side transparent electrode. The buffer layer includes titanium oxide (TiOx).

Abstract: Described herein is a photovoltaic device operable to convert light to electricity, comprising a substrate, one or more structures essentially perpendicular to the substrate, and a reflective layer disposed on the substrate, and one or more junctions conformally disposed on the one or more structures.

Abstract: A conductive paste for forming a solar cell electrode, including: a conductive powder comprising silver as a main component; glass frit; and an organic vehicle, wherein the glass frit contains tellurium glass frit having tellurium oxide as a network-forming component. The conductive paste of the present invention makes it possible to form a solar cell electrode having a low dependence on firing temperature without causing problems due to fire-through into the substrate, and to thereby obtain a solar cell having good solar cell characteristics.

Abstract: There is provided a solid-state imaging device including a semiconductor base element, an organic photoelectric conversion layer formed above the semiconductor base element, a contact hole formed in an insulating layer on the semiconductor base element, a conductive layer formed in the contact hole and electrically connecting a photoelectric conversion part which includes the organic photoelectric conversion layer with the semiconductor base element, and a contact portion which is formed by self-alignment with the conductive layer in the contact hole in the semiconductor base element, and connected to the conductive layer.

Abstract: A stack of a first anti-reflective coating (ARC) layer and a titanium layer is formed on a front surface of a semiconductor substrate including a p-n junction, and is subsequently patterned so that a semiconductor surface is physically exposed in metal contact regions of the front surface of the semiconductor substrate. The remaining portion of the titanium layer is converted into a titania layer by oxidation. A metal layer is plated on the metal contact regions, and a copper line is subsequently plated on the metal layer or a metal semiconductor alloy derived from the metal layer. A second ARC layer is deposited over the titania layer and the copper line, and is subsequently patterned to provide electrical contact to the copper line.

Abstract: A coating for reducing interaction between a surface and the environment around the surface includes an alkali silicate glass material configured to protect the surface from environmental corrosion due to water or moisture. The alkali silicate glass material is doped with a first element to affect various forms of radiation passing through the coating. The electromagnetic radiation is at least one of ultraviolet, x-ray, atomic (gamma, alpha, beta), and electromagnetic or radio wave radiation. The coating may also be used to protect a solar cell from the environment and UV rays while retransmitting received light as usable light for conversion into electrical energy. The coating may also be used to prevent whisker formation in metal finishes of tin, cadmium, zinc, etc.

Abstract: A semiconductor device is provided. The semiconductor device includes metallization layers supported by a substrate, a diode and a partially doped silicon layer disposed over the metallization layers, a buffer layer disposed over the diode and the partially doped silicon layer; and an anti-reflective coating disposed over the buffer layer, the anti-reflective coating formed from a porous silicon.

Abstract: An image sensor includes a dielectric layer including a reflector, a photo-electric conversion region on the dielectric layer, and a resonance layer on the photo-electric conversion region, the resonance layer including ribbed materials arranged in a concentric pattern.

Abstract: A semiconductor device including a substrate and an anti-reflective coating disposed upon the substrate, the anti-reflective coating and the substrate forming an interface, a carbon concentration and a chlorine concentration less than an oxygen concentration at the interface.

Abstract: A method for producing a photosensitive integrated circuit including producing circuit control transistors, producing, above the control transistors, and between at least one upper electrode and at least one lower electrode, at least one photodiode, by amorphous silicon layers into which photons from incident electromagnetic radiation are absorbed, producing at least one passivation layer, between the lower electrode and the control transistors, and producing, between the control transistors and the external surface of the integrated circuit, a reflective layer capable of reflecting photons not absorbed by the amorphous silicon layers.