Abstract: A method of forming a crystalline layer includes: disposing a heating layer on a substrate, wherein the heating layer is separated from the substrate by a support structure; and forming a crystalline layer on the heating layer using heat generated from the heating layer.

Abstract: A method of forming a Group IBIIIAVIA solar cell absorber, which includes a top surface region of less than or equal to 300 nm depth. The Ga/(Ga+In) molar ratio within the top surface region is in the range of 0.1-0.3. The Group IBIIIAVIA solar cell absorber is formed by reacting the layers of a multilayer material structure which includes a metallic film including at least Cu and In formed on a base, a separator layer including Se is formed on the metallic film, a metallic source layer substantially including Ga formed on the separator layer, and a cap layer substantially including Se formed on the source layer.

Abstract: The present invention relates to an organic dye-sensitized photoelectric conversion device and a solar cell utilizing the same. In accordance with a demand to now for development of an organic dye-sensitized photoelectric conversion device with high conversion efficiency and high practicability using an inexpensive dye, there is provided in the present invention, a photoelectric conversion device with high conversion efficiency by producing a photoelectric conversion device by sensitizing fine semiconductor particles with a methine dye having specified skeleton.

Abstract: A method of producing a thermoelectric conversion element includes preparing a dispersion liquid by mixing slurry containing ceramic particles with salts of at least two elements that constitute a thermoelectric conversion material, and then, precipitating the at least two elements that constitute the thermoelectric conversion material on the ceramic particles in the dispersion liquid; performing washing; performing heating treatment; and performing sintering. Contact between a solution with a pH lower than 1 among solutions of the salts and the slurry containing the ceramic particles is avoided, or the solution with the pH lower than 1 contacts the slurry containing the ceramic particles for a first time when the at least two elements that constitute the thermoelectric conversion material are precipitated.

Abstract: A solar energy conversion package includes a photovoltaic (PV) cell, a thermionic or thermoelectric conversion unit and a thermal heating system. Solar radiation is concentrated by a lens or reflector and directed to the PV cell for electrical power conversion. A water circulation system maintains the PV cell at working temperatures. The thermionic or thermoelectric conversion cell is coupled between these cells in the thermal path to generate additional power. Additional efficiencies may be gained by partitioning the solar radiation with prisms or wavelength specific filters or reflective coatings into discrete spectrum segments optimized for each conversion unit for maximizing efficiency of electrical energy conversion and equipment design. Integrating all three of these conversion techniques produces a synergistic system that exceeds the performance conventional solar conversion systems.

Abstract: A shingle having butt and tab portions is provided, wherein the tab portions are exposed when applied to a roof, and wherein active photovoltaic element(s) appear on portions only of the tab portions of the shingles, wherein adjacent zones of the tab portions of the shingles to which the photovoltaic element(s) are applied are free of active photovoltaic elements. The shingles are applied to a roof or a major portion of a roof, laid up in courses so that exposed tab portions of next-overlying courses cover unexposed butt portions of next-underlying courses, leaving photovoltaic elements exposed. In an array of shingles on a roof, the photovoltaic elements are distributed substantially uniformally. The surface ornamentation of the exposed surfaces of the photovoltaic elements may be either complementary to the exposed surfaces of the shingles not having photovoltaic elements thereon, or may blend with such zones not having photovoltaic elements thereon.

Abstract: A chalcopyrite semiconductor based photovoltaic solar cell. This cell comprises a metal substrate. A conductive layer is present between the metal substrate and a chalcopyrite semiconductor. The conductive layer has a crystal structure fitting to the crystal structure of the chalcopyrite semiconductor. Also disclosed is a coated metal substrate, in particular a metal strip for producing the individual metal substrates of a solar cell, as well as a manufacturing method thereof.

Abstract: The invention, in one aspect, provides a photovoltaic cell including a charge carrier material and a photosensitized interconnected nanoparticle material including nanoparticles linked by a polymeric linking agent, both disposed between first and second rigid, significantly light-transmitting substrates. In one embodiment, the charge carrier material and the photosensitized interconnected nanoparticle material are disposed between a first and second flexible, significantly light-transmitting substrate that are themselves disposed between the first and second rigid, significantly light-transmitting substrates.

Abstract: An apparatus is provided comprising a compound parabolic concentrating (CPC) trough, a target, a plurality of sunlight diverters, and a tracker. The CPC trough is for concentrating sunlight and is symmetric about an imaginary plane of symmetry. The target is for absorbing sunlight concentrated by the trough. The plurality of sunlight diverters is to increase the sunlight received by the trough. The tracker is to orient the trough so that the sun is positioned on the plane of symmetry.

Abstract: The energy conversion system includes a first optical cover having a flat surface and a patterned surface. The patterned surface is configured to receive solar energy from the flat surface, then concentrate and guide the solar energy. The system also includes a second optical cover. The system further includes providing a photovoltaic cell layer between the patterned surface of the first optical cover and the second optical cover. The photovoltaic cell layer is configured to receive the solar energy from the patterned surface and convert the solar energy into electrical energy.

Abstract: In one embodiment, a solar cell has base and emitter diffusion regions formed on the back side. The emitter diffusion region is configured to collect minority charge carriers in the solar cell, while the base diffusion region is configured to collect majority charge carriers. The emitter diffusion region may be a continuous region separating the base diffusion regions. Each of the base diffusion regions may have a reduced area to decrease minority charge carrier recombination losses without substantially increasing series resistance losses due to lateral flow of majority charge carriers. Each of the base diffusion regions may have a dot shape, for example.

Abstract: The thermoelectric device of the present invention includes a first electrode and a second electrode that are disposed to be opposed to each other, and a laminate that is interposed between the first electrode and the second electrode, is connected electrically to both the first electrode and the second electrode, and is layered in the direction orthogonal to an electromotive-force extracting direction, which is the direction in which the first electrode and the second electrode are opposed to each other.

Abstract: A stacked photovoltaic apparatus capable of improving the output characteristics is provided. This stacked photovoltaic apparatus comprises a second power generation unit including a second semiconductor layer having a first refractive index and a third semiconductor layer of an amorphous semiconductor functioning as a photoelectric conversion layer, an intermediate layer formed between a first power generation unit and the second power generation unit with a second refractive index and a reflection promotive layer formed between the intermediate layer and the second power generation unit with such a third refractive index that the difference between the third refractive index and the first refractive index is larger than the difference between the second refractive index and the first refractive index.

Abstract: A photovoltaic device capable of suppressing reduction of the yield in production also when a transparent conductive film has small surface roughness is obtained. This photovoltaic device comprises a photovoltaic element including a transparent conductive oxide film having arithmetic mean deviation of the profile of not more than about 2 nm and a paste electrode, formed on the transparent conductive oxide film, containing at least a metal material and a resin material, while the resin material contains at least about 60 percent by weight and not more than about 100 percent by weight of epoxy resin.

Abstract: A back metal electrode, a bottom cell using microcrystalline silicon for a photoelectric conversion layer, a front cell using amorphous silicon for a photoelectric conversion layer, and a transparent front electrode are formed in this order on a supporting substrate. At least one of the concentration of impurities contained in the front photoelectric conversion layer and the concentration of impurities contained in the bottom photoelectric conversion layer is controlled such that the concentration of impurities in the bottom photoelectric conversion layer is higher than the concentration of impurities in the front photoelectric conversion layer. Impurities do not include a p-type dopant or an n-type dopant but are any one, two, or all of carbon, nitrogen, and oxygen.

Abstract: A photovoltaic device may include a housing having a transparent pupil receiving a collimated beam of radiation, and photovoltaic cell arrays being positioned on respective inner surfaces of the housing, each photovoltaic cell array sensing a respective spectral range of the radiation different from the other photovoltaic cell arrays. The photovoltaic device may further include dichroic filters being positioned along an optical axis of the transparent pupil and splitting the collimated beam into a corresponding divided beams of different spectrums, and mirrors corresponding to the divided beams. Each mirror may have reflecting surfaces, receive a respective divided beam, subdivide the received divided beam into reflected beams from the reflecting surfaces, and illuminate an active area of a photovoltaic cell of the respective array.

Abstract: A photovoltaic power module (10), comprising a substrate (12) provided with a circuit, one or more photovoltaic cells (16) mounted to the substrate and electrically connected to the circuit, and one or more bypass diodes (20), each corresponding to a respective one or more of the cells, wherein each of the diodes is located between the substrate and the cells and between conducting portions (14) of the circuit. Solder (18) connects the bypass diode, the conducting portions, and the photovoltaic cell.

Abstract: A method for producing a solar cell including the steps of forming a p-type microcrystalline silicon oxide layer on a glass substrate using a PECVD method and raw gases comprising Silane gas, Diborane gas, Hydrogen gas and Carbon Dioxide gas. The method may employ a frequency of between about 13.56-60 MHz. The PECVD method may be performed at a power density of between about 10-40 mW/cm2 and a pressure of between about 0.5-2 Torr, and with a ratio of Carbon Dioxide to Silane of between about 0.10-0.24; a ratio of Diborane to Silane of 0.10 or less, and a ratio of Silane to Hydrogen of 0.01 or less. A tandem solar cell structure may be formed by forming top and bottom layers by the method described above, and placing the top layer over the bottom layer.

Abstract: A photoelectric conversion device comprising an organic dye-sensitizing semiconductor fine particle thin film is prepared by using a dye having a barbituric acid structure as a partial structure and by adsorbing the dye on a semiconductor thin film electrode, and thereby a low-cost photoelectric conversion device having high conversion efficiency, and a solar cell using the device are provided.

Abstract: A flexible inflatable hinge includes curable resin for rigidly positioning panels of solar cells about the hinge in which wrap around contacts and flex circuits are disposed for routing power from the solar cells to the power bus further used for grounding the hinge. An indium tin oxide and magnesium fluoride coating is used to prevent static discharge while being transparent to ultraviolet light that cures the embedded resin after deployment for rigidizing the inflatable hinge.