Abstract: A light-harvesting material comprises a perovskite absorber doped with a metal chalcogenide. The light-harvesting material may be used in a photovoltaic device, comprising (1) a first conductive layer, (2) an optional blocking layer, on the first conductive layer, (3) a semiconductor layer, on the first conductive layer, (4) a light-harvesting material, on the semiconductor layer, (5) a hole transport material, on the light-harvesting material, and (6) a second conductive layer, on the hole transport material.

Abstract: A photovoltaic device and method include a crystalline substrate and an emitter contact portion formed in contact with the substrate. A back-surface-field junction includes a homogeneous junction layer formed in contact with the crystalline substrate and having a same conductivity type and a higher active doping density than that of the substrate. The homogeneous junction layer includes a thickness less than a diffusion length of minority carriers in the homogeneous junction layer. A passivation layer is formed in contact with the homogeneous junction layer opposite the substrate, which is either undoped or has the same conductivity type as that of the substrate.

Abstract: Micro-structures and directional and multi-directional coatings for uniformly colored and directionally colored photovoltaic modules and roof tiles are described. The photovoltaic roof tiles include a glass cover with texture of a micro scale on a first side, and one or more layers of a transparent material adjoining the first side of the textured glass configured to reflect light of a color. A glass cover can have texture on a first side and a layer of sphere shaped metal nanoparticles adjoining the first side of the textured glass cover. Directionally colored solar modules can include a textured glass cover with texture on a first side and a coating layer covering one or more facets of the texture on the first side of the glass cover. The coating layer may be deposited by coating the textured glass cover in one or more directions.

Abstract: The present invention provides a solar panel installation, comprising at least one solar panel comprising photovoltaic cells, and a translucent plate on the upper side, wherein the translucent plate is provided with an electrically conductive layer that is provided in order to have an electric potential applied to it and which is electrically isolated from the photovoltaic cells, such that an electric potential applied to the electrically conductive layer will be uniformly distributed over the upper side of the at least one solar panel. In addition, the invention provides a method for applying the electrically conductive layer and for regenerating and/or preventing defects in the at least one solar panel.

Abstract: A solar panel awning device may include a solar panel having first and second opposing ends, first and second opposing sides extending between the first and second opposing ends, and first and second opposing major surfaces. The first major opposing surface defines a photovoltaic surface. The solar panel awning device may include first and second arms respectively coupled to the first and second opposing ends of the solar panel, and an actuator coupled to one of the first and second arms and configured to switch the solar panel between an extended position and a retracted position. In the retracted position, the solar panel is flat against a side of a building; in the extended position, the first opposing side is proximal to the side of the building and spaced apart from the side of the building; and the second opposing side is distal to the side of the building.

Abstract: A solar cell module capable of preventing the occurrence of a PID failure in a solar photovoltaic power generation system with a MW capacity, said system being used in a high-temperature high-humidity environment; and a method for manufacturing this solar cell module. A solar cell module which comprises a protection glass material and a sealing material on a light receiving surface side of a substrate, and which also comprises an oxide layer between the substrate and the protection glass material, said oxide layer containing a metal element and silicon. It is preferable that the oxide layer contains at least one metal element selected from the group consisting of magnesium, aluminum, titanium, vanadium, chromium, manganese, zirconium, niobium and molybdenum. It is also preferable that the oxide layer has a refractive index of from 1.5 to 2.3 (inclusive) with respect to incident light having a wavelength of 587 nm.

Abstract: The invention discloses nanocrystalline (NC) FeS2 thin films as the back contact for CdTe solar cells. In one example, the FeS2 NC layer is prepared from a solution directly on the CdTe surface using spin-casting and chemical treatment at ambient temperature and pressure, without a thermal treatment step. Solar cells prepared by applying the NC FeS2 back contact onto CdTe yield efficiencies of about 95% to 100% that of standard Cu/Au back contact devices. In another example, FeS2 is interposed between Cu and Au to form a Cu/FeS2 NC/Au back contact configuration yielding an efficiency improvement of 5 to 9 percent higher than standard Cu/Au devices.

Abstract: A composition of matter, in particular a photovoltaic cell, comprising: at least one core semiconductor nanowire on a graphitic substrate, said at least one core nanowire having been grown epitaxially on said substrate wherein said nanowire comprises at least one group III-V compound or at least one group II-VI compound or at least one group IV element; a semiconductor shell surrounding said core nanowire, said shell comprising at least one group III-V compound or at least one group II-VI compound or at least one group IV element such that said core nanowire and said shell form a n-type semiconductor and a p-type semiconductor respectively or vice versa; and an outer conducting coating surrounding said shell which forms an electrode contact.

Abstract: A light scattering-based solar concentrator (LSSC) uses high refractive index nanoparticles (NPs) as dopants to selectively scatter photons across the solar spectrum without spectroscopic conversion by different sized nanoparticles. The LSSCs are limited by a single parameter: the surface photon losses, which can be addressed by nanofabrication to implement anti-reflective and light trapping structures into LSSC designs. The LSSC design provides solar concentrator techniques for photovoltaic (PV) applications.

Abstract: A photovoltaic cell comprises a first subcell formed of a Group IV semiconductor material, a second subcell formed of a Group II-VI semiconductor material, and a tunnel heterojunction interposed between the first and second subcells. A first side of the tunnel heterojunction is formed by a first layer that is adjacent to a top surface of the first subcell. The first layer is of a first conductivity type, is comprised of a highly doped Group IV semiconductor material. The other side of the tunnel heterojunction is formed by a second layer that adjoins the lower surface of the second subcell. The second layer is of a second conductivity type opposite the first conductivity type, and is comprised of a highly doped Group II-VI semiconductor material. The tunnel heterojunction permits photoelectric series current to flow through the subcells.

Abstract: Thin-film photovoltaic devices and methods of their use and manufacture are disclosed. More particularly, polycrystalline CuIn(1-x)GaxSe2 (CIGS) based thin-film photovoltaic devices having independently tunable sublayers are disclosed. Also provided are methods of producing an n-doped graphene.

Abstract: Methods and apparatus are provided for converting electromagnetic radiation, such as solar energy, into electric energy with increased efficiency when compared to conventional solar cells. One embodiment of the present invention provides a photovoltaic (PV) device. The PV device comprises an absorber layer made of a compound semiconductor; and an emitter layer located closer than the absorber layer to a first side of the device. The PV device includes a p-n junction formed between the emitter layer and the absorber layer, the p-n junction causing a voltage to be generated in the device in response to the device being exposed to light at a second side of the device. Such innovations may allow for greater efficiency and flexibility in PV devices when compared to conventional solar cells.

Abstract: A photovoltaic cell can include a dopant in contact with a semiconductor layer.

Abstract: A solar cell system is formed with a dynamic surface relief grating. Movement members are actuated by a controller to produce a force on the reflective surface. The reflective surface deforms in response to the force creating a surface relief grating that can adapt to changing light conditions.

Abstract: A dye-sensitized solar cell can include a plurality of a plasmon-forming nanostructures. The plasmon-forming nanostructures can include an oxide core, an inner metallic shell on a surface of the oxide core, and an outer oxide shell on a surface of the inner metallic shell.

Abstract: A solar cell can include a substrate of a first conductive type; an emitter region which is positioned at a front surface of the substrate and has a second conductive type different from the first conductive type; a back surface field region which is positioned at a back surface opposite the front surface of the substrate; a front passivation region including a plurality of layers which are sequentially positioned on the emitter region; a back passivation region including a plurality of layers which are sequentially positioned on the back surface field region; a front electrode part which passes through the front passivation region and is connected to the emitter region, wherein the front electrode part comprises a plurality of front electrodes that are apart from each other and a front bus bar connecting the plurality of front electrodes; a back electrode part which passes through the back passivation region and is connected to the back surface field region, wherein the back electrode part comprises a plural

Abstract: Problem addressed: how to decrease the loss of visual quality in an image that appears when this image is placed behind a semitransparent photovoltaic sheet or film. Solution: on the one hand, increase the luminosity of the image by depositing a white-colored or metallic or reflective layer on the side of the photovoltaic cells that is turned towards the image; and on the other hand, by modifying the luminosity, the contrast, and the color saturation of the image.

Abstract: A solar cell module according to an embodiment includes: a light transmissive first substrate; a second substrate; at least one cell array disposed between the first substrate and the second substrate, the cell array including a plurality of cells arranged, each of the cells including a first electrode disposed on the first substrate, an organic photoelectric conversion film disposed on the first electrode, and a second electrode disposed on the organic photoelectric conversion film; a plurality of light transmissive partition walls disposed at portions on the first substrate, the portions being located between adjacent ones of the cells and at both end portions of the cell array; and a first resin film disposed between the second substrate and each of the cells between adjacent ones of the partition walls, the cells being connected in series.

Abstract: Submitted is a modular stationary portable photovoltaic solar powered electrical generation, storage and supply device and light tower. The device consists of an elongated cube or rectangular prism shaped support structure with a flat base, flat sides and a flat decked top to form a protective crate shaped module when the various components, such as the solar panel arrays, telescoping mast, and light assembly or outriggers of the device are retracted to where the boundaries may be defined by the perimeters of the cube or prism. This modular design can allow for the modules to be stored, loaded, or shipped quickly, efficiently, and in greater quantities on flatbeds, in shipping containers, in warehouses, and other settings and modes where they can not only be packed end to end and side to side with no unused space, but can also be stacked up to three modules high for significantly higher storage density.

Abstract: A device and method for generating electricity. The device includes a heat source, a cold source, and a thermoelectric generating plate, having a first side and an opposed side. When heat is introduced to the heat source, heat flows across the thermoelectric generating plate and electricity is generated. In the present arrangement, because the hot and cold sources are in thermal communication with opposed sides of the thermoelectric generating plate, the thermal gradient or rate of heat flow across the thermoelectric generating plate is maximized. Thus, because the rate of heat flow is increased, the rate at which electricity is generated is also increased, and the size of the device is maintained, or minimized.