Abstract: Provided are a solar cell sheet and a heat treatment process thereof The heat treatment process includes: a) sifting from solar cell sheets after printed and sintered cell sheets with conversion efficiency lower than 18% and filling factor thereof higher than 70%; h) performing low temperature annealing on the sifted cell sheets; c) sifting from the cell sheets after low temperature annealing cell sheets with lowered filling factor; d) re-sintering the sifted cell sheets; and e) sifting from the re-sintered cell sheets cell sheets with conversion efficiency lower than 18% and returning back to b) until most or all of the sifted meet demands.

Abstract: An efficient solar cell and method of fabricating the same is disclosed. The solar cell includes an n-doped substrate layer. A p-doped buffer layer is disposed on the n-doped substrate layer. A quantum dot absorber stack is disposed on the buffer layer. The absorber stack includes at least one quantum dot layer and one p-doped spacer layer. A p-doped cap layer is disposed on the quantum dot absorber layer. The thickness of the quantum dot layer is less than an electron diffusion length from the depletion region formed by the n-doped substrate layer and the p-doped buffer layer. The quantum dot absorber layer allows for additional photo currents from two-photon absorption from the p-doped cap layer being exposed to a light source.

Abstract: Formulations and methods of making solar cell contacts and cells therewith are disclosed. The invention provides a photovoltaic cell comprising a front contact, a back contact, and a rear contact. The back contact comprises, prior to firing, a passivating layer onto which is applied a paste, comprising aluminum, a glass component, wherein the aluminum paste comprises, aluminum, another optional metal, a glass component, and a vehicle. The back contact comprises, prior to firing, a passivating layer onto which is applied an aluminum paste, wherein the aluminum paste comprises aluminum, a glass component, and a vehicle.

Abstract: A photoelectric conversion element comprising: a photoelectric conversion layer; and a plurality of metal nanoparticles arranged in the form of a two-dimensional array on the photoelectric conversion layer on its principal face side that is opposite to its light receiving face, wherein the plurality of metal nanoparticles are arranged with a particle density that is equal to or greater than 5.0×108/cm2 and is equal to or smaller than 3.0×109/cm2.

Abstract: A solar battery according to the embodiment of the present invention comprises a plurality of solar battery cells formed on a first area of a substrate to include a rear electrode pattern, a light-absorbing layer, a buffer layer and a front electrode layer respectively; a metal film pattern formed on a second area of the substrate to electrically connect to each a plurality of solar battery cells and space each other; and a connection unit formed between the mutually spaced metal film patterns.

Abstract: A photovoltaic device including a protective layer between a window layer and an absorber layer, the protective layer inhibiting dissolving/intermixing of the window layer into the absorber layer during a device activation step, and methods of forming such photovoltaic devices.

Abstract: Aim of the present invention is to obtain cementitious products having smooth, planar surfaces and low thickness for applications having aesthetic purpose, of integrated architecture or as substrates, for example for a thin-film photovoltaic unit, with controlled curling and surface roughness, manufactured by mould casting of a fluid composition comprising: I. a hydraulic binder; II. one or more aggregates; III. an anti-shrinkage agent; IV. a superplasticizer agent; V. water, wherein the percentage by weight of said hydraulic binder in the composition is lower than that of said aggregates, and wherein said aggregates have a maximum diameter dmax not greater than one third of the thickness of the product, the final product thus having an arithmetic mean surface roughness Ra not greater than 500 nm and curling not greater than 1500 micron.

Abstract: A co-sensitized dye-sensitized solar cell (DSC) is provided, made from a transparent substrate and a transparent conductive oxide (TCO) film overlying the transparent substrate. An n-type semiconductor layer overlies the TCO, and is co-sensitized with a first dye (D1) and a second dye (D2). A redox electrolyte is in contact with the co-sensitized n-type semiconductor layer, and a counter electrode overlies the redox electrolyte. The first dye (D1) has a first optical absorbance local maxima at a first wavelength (A1) and a second optical absorbance local maxima at a second wavelength (A2), longer than the first wavelength. The second dye (D2) has a third optical absorbance local maxima at a third wavelength (A3) between the first wavelength (A1) and the second wavelength (A2). In one aspect, the first dye (D1) includes a porphyrin material, for example, a metalloporphyrin obtained by complexation with a transition metal such as zinc (i.e. zinc porphyrin (ZnP)).

Abstract: A multi-layered film, a method of preparing the same and a photovoltaic module are provided. A barrier film having excellent moisture barrier properties can be coated with a fluoropolymer having excellent weather resistance by means of a primer layer including a silane-modified acrylic copolymer, and an interfacial adhesive strength can also be ensured. As a result, a multi-layered film having excellent durability and weather resistance and simultaneously exhibiting a high interfacial adhesive strength to the barrier film can be provided. In preparation of the multi-layered film, the manufacturing cost can also be reduced, productivity can be enhanced, and degradation of product qualities caused by thermal deformation or thermal shock can be prevented. Therefore, the multi-layered film can be effectively used as a backsheet for various photovoltaic modules.

Abstract: A method of fabricating a solar cell includes forming a front contact layer over a substrate, and the front contact layer is optically transparent at specified wavelengths and electrically conductive. A first scribed area is scribed through the front contact layer to expose a portion of the substrate. A buffer layer doped with an n-type dopant is formed over the front contact layer and the first scribed area. An absorber layer doped with a p-type dopant is formed over the buffer layer. A back contact layer that is electrically conductive is formed over the absorber layer.

Abstract: In order to provide a see-through solar cell module in which the manufacturing costs can be reduced and transmittance can be readily modified without modifying the manufacturing steps, there is provided a solar cell module comprising solar cells in which are layered a conductive substrate, and a lower electrode layer, a photoelectric conversion layer, and an upper electrode layer in the stated order on the conductive substrate; the solar cell module having a configuration in which a plurality of through-openings that pass through the conductive substrate to the upper electrode layer in the layering direction is formed over the entire surface of the solar cells.

Abstract: Devices and methods for enhancing optical absorbance and photovoltaics are disclosed. In some embodiments, a light absorbing device comprises a light absorbing material having a front surface and a back surface, and a planar array of nanostructures embedded within the light absorbing material between the front surface and the back surface of the light absorbing material. The nanostructures may be formed from a metallic material.

Abstract: The present invention provides a method and apparatus for providing an integrated electrochemical and solar cell. In one embodiment of the invention, an electrochemical cell with a self supporting ceramic cathode layer is electrically connected to a solar cell. In another embodiment of the invention, an electrochemical cell with a self supporting anode is provided. The present invention also contemplates methods of manufacturing the integrated electrochemical and solar cell wherein such methods provide weight savings and streamlined manufacturing procedures through the use of self supporting cathodes and anodes.

Abstract: Novel structures of photovoltaic cells (also called as solar cells) are provided. The cells are based on nanoparticles or nanometer-scaled wires, tubes, and/or rods, which are made of electronic materials covering semiconductors, insulators, and may be metallic in structure. These photovoltaic cells have large power generation capability per unit physical area over the conventional cells. These cells will have enormous applications such as in space, commercial, residential and industrial applications.

Abstract: A photoelectrochemical cell (1) includes an electrolyte container (3) containing an ionic liquid (2), and a partitioning membrane (4) dividing an interior of the electrolyte container (3) into two being a CO2 capturing chamber (7) and a CO2 releasing chamber (8), having side walls opposing each other, with the partitioning membrane (4) in between, either as a carbon electrode (5) and the other as a photoelectrode (6). A redox mediator (B) has different bonding forces to carbon dioxide, as it appears as an oxidant Box and a reductant Bred, of which that one which has a greater bonding force serves as an intermediary chemical species carrying carbon dioxide to one of the paired electrodes (5, 6). Over the CO2 releasing chamber (10), an upper wall portion (10) is formed, which has a CO2 take-out port (10A) formed therein, for making use of oxidation and reduction of the redox mediator to achieve separation and concentration of carbon dioxide, converting photo energy of sunlight into electric power.

Abstract: This invention is related to energy scavenging device and in particular, to energy harvesting or scavenging from the environmental radiation covering from solar spectrum and thermal radiation. Energy harvesting device is an integrated device comprising the devices that capture the radiation and converted into electrons, and also energy management devices to manage the converted energy either to store, to operate the electronic devices, and/or recharge the batteries. The energy scavenging devices integrates several device capabilities such as energy conversion, management, and storing the energy, on a common platform. Herein a design of a device capable to scavenge or harvest the energy from environment radiation is disclosed. A primary objective of this invention is to provide a design of a scavenging device that harvests the energy from environment radiation, operates 24/7, thereby generate and store, manage the energy as required.

Abstract: A novel photoelectric conversion device in which energy of light can be effectively utilized and performance can be improved is provided. A photoelectric conversion device includes a photoelectric conversion element and an energy conversion layer provided on a light-receiving side of a photoelectric conversion layer included in the photoelectric conversion element. The energy conversion layer includes a plurality of first layers and a plurality of second layers. The first layer and the second layer are alternately stacked. The thickness of the first layer is greater than or equal to 0.5 nm and less than or equal to 10 nm, and the thickness of the second layer is greater than or equal to 0.5 nm and less than or equal to 10 nm. The second layer can be formed using a material having a larger energy band gap than that of a material used for the first layer.

Abstract: An electrolyte composition containing an ionic liquid and conductive particles, an electrolyte composition containing an ionic liquid and oxide semiconductor particles and optionally containing conductive particles, and an electrolyte composition containing an ionic liquid and insulating particles are provided. Furthermore, a photoelectric conversion element comprising: a working electrode, the working electrode comprising an electrode substrate and an oxide semiconductor porous film formed on the electrode substrate and sensitized with a dye; a counter electrode disposed opposing the working electrode; and an electrolyte layer made of these electrolyte compositions is provided.

Abstract: Nanostructures are joined using one or more of a variety of materials and approaches. As consistent with various example embodiments, two or more nanostructures are joined at a junction between the nanostructures. The nanostructures may touch or be nearly touching at the junction, and a joining material is deposited and nucleates at the junction to couple the nanostructures together. In various applications, the nucleated joining material facilitates conductivity (thermal and/or electric) between the nanostructures. In some embodiments, the joining material further enhances conductivity of the nanostructures themselves, such as by growing along the nanostructures and/or doping the nanostructures.

Abstract: The process for making silver powder particles with small size crystallites uses a combination of gum arabic and maleic acid with the reduction of a silver salt with ascorbic acid, Silver thick film paste containing these silver powder particles can be used in electronic applications to form electrodes for semiconductor devices and, in particular, solar cells.

Abstract: Disclosed are a solar cell apparatus and a method for manufacturing the same. The solar cell apparatus includes a substrate; a back electrode layer on the substrate; a light absorbing layer on the back electrode layer; and a front electrode layer on the light absorbing layer, wherein an outer peripheral side of the back electrode layer is aligned on a plane different from a plane of an outer peripheral side of the light absorbing layer.

Abstract: A solar cell includes a semi-conductive substrate, a doping layer, an anti-reflection layer, an electrode, a passivation stacked layer and a contact layer. The semi-conductive substrate has a front and a back surface. The doping layer is disposed on the front surface. The anti-reflection layer is disposed on the doping layer. The electrode is disposed on the anti-reflection layer and electrically connected to the doping layer. The passivation stacked layer is disposed on the back surface and has a first dielectric layer, a second dielectric layer and a middle dielectric layer sandwiched between the first and the second dielectric layer. The dielectric constant of the middle dielectric layer is substantially lower than the dielectric constant of the first dielectric layer and the dielectric constant of the second dielectric layer. The contact layer covers the passivation stacked layer and electrically contacts with the back surface of the semi-conductive substrate.

Abstract: Disclosed are aluminum paste compositions, processes to form solar cells using the aluminum paste compositions, and the solar cells so-produced. The aluminum paste compositions comprise 0.003% to 9%, by weight of boron nitride; 27% to 89%, by weight of an aluminum powder, such that the weight ratio of aluminum powder to boron nitride is in the range of 9:1 to 9909:1; and 0.1% to 9%, by weight of an optional glass frit-free additive, the optional glass frit-free additive comprising amorphous silicon dioxide, crystalline calcium oxide organometallic compounds, metal salts, or mixtures thereof; and 10% to 70%, by weight of an organic vehicle, wherein the amounts in % by weight are based on the total weight of the aluminum paste composition.

Abstract: The present invention provides an integrated wiring member (46, 47, 48) for a solar cell module, including a first wiring member, a second wiring member, and an insulating and protecting film for insulating the first wiring member and the second wiring member from each other. Herein, the first wiring member and the second wiring member are integrated with each other through the insulating and protecting film.

Abstract: A solar cell and a method of manufacturing the same are disclosed. The solar cell includes a first doped region of a first conductive type formed on a semiconductor substrate of the first conductive type, a second doped region of a second conductive type opposite the first conductive type formed on the semiconductor substrate at a location adjacent to the first doped region, a passivation layer exposing a portion of each of the first and second doped regions, a first electrode formed on the exposed portion of the first doped region, and a second electrode formed on the exposed portion of the second doped region. The first electrode includes a metal seed layer directly contacting the first doped region, and the second electrode includes a metal seed layer directly contacting the second doped region.

Abstract: The present invention is directed to a thick film silver paste comprising (i) silver, (ii) Al2O3, and (iii) a Pb—Te—O all dispersed in an organic medium. The present invention is further directed to an electrode formed from the paste and a semiconductor device and, in particular, a solar cell comprising such an electrode. The electrodes provide good adhesion and good electrical performance.

Abstract: The disclosure relates to apparatus and methods of photovoltaic or solar module design and fabrication. A photovoltaic (PV) module includes one or more photovoltaic cells mounted to a support, a first terminal connected to at least one of the one or more PV cells, a second terminal connected to at least one of the one or more PV cells, and a bypass line mounted to the support for bypassing the one or more PV cells. It is emphasized that this abstract is provided to comply with the rules requiring an abstract that will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

Abstract: Optical absorbers, solar cells comprising the optical absorbers, and methods for making the absorbers are disclosed. The optical absorber comprises a layer comprising a semiconductor having a bandgap of between about 1.0 eV and about 1.6 eV on a substrate. The thickness of the layer is from about 1 to about 10 microns. The semiconductor comprises Fe, at least one Group IVA element, and at least one Group VIA element. The Group VIA element can be S, Se or Te. The Group IVA element can be Si or Ge. Typical compositions are Fe2(Si,Ge)(S,Se)4. The bandgap can be graded through the thickness of the absorber. High Productivity Combinatorial methods can be used to optimize the composition and grading.

Abstract: Provided are a solar cell and a method of manufacturing the same. The method includes: preparing a bottom substrate including sequentially stacked first and second portions, each of the first and second portions including a plurality of grains, wherein the maximum grain size of the second portion is less than the minimum grains size of the first portion; exposing the first portion of the bottom substrate by removing the second portion of the bottom substrate; and forming a photovoltaic conversion layer on the first portion of the bottom substrate.

Abstract: The present invention relates to a transparent chemically functionalized graphene with high electrical conductivity and which is stable in air. It also relates to a method of manufacturing a conductive and transparent graphene-based material.

Abstract: An apparatus includes a photovoltaic device (PVD) having a quantum dot (QD) array structure that is capable of performing wavelength conversion. The PVD is configured to generate charge carriers from incident photons. An electric field generator is operable to apply an electric field to the PVD. Strength of the electric field is sufficient to cause the charge carriers to transition through a plurality of discrete energy states formed within a corresponding one of a conductive band and a valence band of the QD array structure. The transition of the charge carriers through the plurality of discrete energy states enables the PVD to generate emitted photons being radiated as an electromagnetic wave. A frequency (and hence wavelength) of the emitted photons being radiated as the electromagnetic wave is tunable by configuring physical attributes of the QD array structure and controlling the electric field strength.

Abstract: An article, such as a photovoltaic device, and methods for making such articles, are provided. For example, one embodiment is an article comprising a plurality of layers comprising an absorber layer and a window stack. The window stack comprises antimony.

Abstract: Methods for improving the efficiency of solar cells are disclosed. A solar cell consistent with the present disclosure includes a back contact metal layer disposed on a substrate. The solar cell also includes an electron reflector material(s) layer formed on the back contact metal layer and an absorber material(s) layer disposed on the electron reflector material(s) layer. In addition, the solar cell includes a buffer material(s) layer formed on the absorber material(s) layer wherein the electron reflector material(s) layer, absorber material(s) layer, and buffer material(s) layer form a pn junction within the solar cell. Furthermore, a TCO material(s) layer is formed on the buffer material(s) layer. In addition, the front contact layer is formed on the TCO material(s) layer.

Abstract: Disclosed is a solar cell including a substrate, a back electrode layer on the substrate, a light absorbing layer on the back electrode layer, a transparent electrode layer on the light absorbing layer, and an impurity diffusion preventing layer between the substrate and the back electrode layer. The impurity diffusion preventing layer is formed on the substrate, so that the impurities come from the substrate during the high-temperature process are prevented from being diffused to the back electrode layer and the light absorbing layer.

Abstract: Provided is a solar cell backsheet including a polymer base material, and a colored layer that is disposed directly on the polymer base material, and that contains a binder having an acid value of 2 mg KOH/g to 10 mg KOH/g and a pigment at a content of 2.5 g/m2 to 8.5 g/m2, and that has an adhesive force of 50 N/cm or more to an ethylene-vinyl acetate encapsulating material.

Abstract: In various embodiments, energy is harvested from a plurality of photons of received light, each photon having energy below an activation energy threshold of a photon activated process. The harvested energy from one or more of the photons is aggregated until the aggregated energy exceeds the activation energy level. The aggregated energy is then outputted, to e.g. a photolytic power source, a photovoltaic power source or a laser gain media.

Abstract: Disclosed are a counter electrode and a dye-sensitized solar cell. The dye-sensitized solar cell includes a photo electrode, the counter electrode and an electrolytic solution. The counter electrode is disposed correspondingly to the photo electrode. The counter electrode includes a conductive layer and a catalytic layer. The catalytic layer is formed on a surface of the conductive layer facing the photo electrode. The catalytic layer includes FeS2. The electrolytic solution is disposed between the photo electrode and the counter electrode. The present invention is capable of significantly decreasing manufacturing costs of the counter electrode and the dye-sensitized solar cell.

Abstract: Provided is a biaxially stretched polyester film in which a thickness is from 200 ?m to 800 ?m, fracture strength in both a longitudinal stretching direction and a lateral stretching direction is from 180 MPa to 300 MPa, an internal haze (Hin) is from 0.3% to 20%, a difference (?H=Hsur?Hin) between an external haze (Hsur) and the internal haze (Hin) is 2% or less, and an intrinsic viscosity is from 0.68 to 0.90, a method of the biaxially stretched polyester film, a solar cell power generation module using the biaxially stretched polyester film.

Abstract: A solar cell includes a substrate; a back electrode layer provided on the substrate; a light absorbing layer provided on the back electrode layer; a transparent electrode layer provided on the light absorbing layer; and an impurity doping layer provided between the light absorbing layer and the transparent electrode layer. In the solar cell, contact resistance during contact of the transparent electrode layer with the back electrode layer is reduced by making an impurity doping amount of the impurity doping layer greater than that of the transparent electrode layer.

Abstract: Provided is a solar module with improved reliability. A solar module (1) is provided with a solar cell (10), a wiring member (11), a resin adhesive layer (12), and a buffer region (40). The wiring member (11) is electrically connected to the solar cell (10). The resin adhesive layer (12) bonds the solar cell (10) and the wiring member (11) to one another. The buffer region (40) is provided at least partially between the wiring member (11) and the solar cell (10). The buffer region (40) contains a non-crosslinked resin.

Abstract: Disclosed are new compound semiconductors which may be used for solar cells or as thermoelectric materials, and their application. The compound semiconductor may be represented by a chemical formula: InxCo4Sb12-zTez, where 0<x?0.5 and 0.8<z?2.

Abstract: A rectangular conductor for a solar battery and a lead wire for a solar battery, in which warping or damaging of a silicon crystal wafer is hard to occur at the time of bonding a connection lead wire even when a silicon crystal wafer is configured to have a thin sheet structure, can be provided. A conductor 1 having a volume resistivity equal to or less than 50 ??·mm, and a 0.2% yield strength value equal to or less than 90 MPa in a tensile test is formed into a rectangular conductor 10 for a solar battery having a rectangular cross section, and a surface of the rectangular conductor 10 for a solar battery is coated with a solder plating film 13, to provide a lead wire 20 for a solar battery.

Abstract: A dye-sensitized solar cell is provided, wherein it can be produced by a relatively easy and simple process and ensures high conversion efficiency even in cases where the thickness of the porous semiconductor layer is increased. The dye-sensitized solar cell 10 includes, in the interior of or on the conductive-substrate-side surface of the porous semiconductor layer 16, conductive metal film 20, such as a film of tungsten, having a large number of randomly located penetrations 24. Penetrations 24 of the conductive metal film 20 are formed by forming a fine-particle layer on the surface of the porous semiconductor layer, forming a conductive metal film on the surface of the fine-particle layer, and making the fine-particle layer disappear by heating or solvent-cleaning.

Abstract: A multilayer anti-reflection structure for a backside contact solar cell. The anti-reflection structure may be formed on a front side of the backside contact solar cell. The anti-reflection structure may include a passivation level, a high optical absorption layer over the passivation level, and a low optical absorption layer over the high optical absorption layer. The passivation level may include silicon dioxide thermally grown on a textured surface of the solar cell substrate, which may be an N-type silicon substrate. The high optical absorption layer may be configured to block at least 10% of UV radiation coming into the substrate. The high optical absorption layer may comprise high-k silicon nitride and the low optical absorption layer may comprise low-k silicon nitride.

Abstract: Photovoltaic devices and methods of making the same are disclosed herein. The cell comprises: a first electrically conductive layer; at least one photoelectrochemical layer comprising metal-oxide particles, an electrolyte solution, an asphaltene dye, and a second electrically conductive layer.

Abstract: A method and apparatus for indicating a disconnection within a Distributed Generator (DG). In one embodiment, the apparatus comprises an alarm module electrically coupled to a conductive portion of a component within the DG, wherein the conductive portion is grounded via a ground rod system, and wherein the alarm module (i) is further coupled to a ground line, (ii) couples a monitoring current to the conductive portion, (iii) monitors flow of the monitoring current to determine a change in the flow, and (iv) generates, as a result of the change in the flow, a notification of the disconnection.

Abstract: Disclosed are new compound semiconductors which may be used for solar cells or as thermoelectric materials, and their application. The compound semiconductor may be represented by a chemical formula: InxCo4-aSb12-zQz, where Q is at least one selected from the group consisting of O, S, Se and Te, 0<x?0.5, 0<a?1 and 0?z?4.

Abstract: A multilayer photovoltaic backsheet comprising a transparent substrate with same polymeric coatings on both sides of the substrate or a different polymeric coating on either side of the substrate. The use of coatings instead of laminated layers provides for a manufacturing process that is faster, has fewer steps, and is more cost effective. Coatings can be tailored to provide excellent adhesion, without the problems of delamination seen in prior art laminated backsheets. The coating for the outer side of the substrate can also be tailored to be softened during module lamination. A patterned blanket or other patterned or textured surface can be pressed against the outer side coating layer during lamination. The pattern or texture is thus transferred to the outer side of the backsheet, which will cause light passing through the backsheet to be diffused. Latent cross-linking reaction can further harden the outer side coating layer to increase the outer side coating layer hardness and to improve its durability.

Abstract: Sodium containing aluminosilicate and boroaluminosilicate glasses are described herein. The glasses can be used as substrates or superstrates for photovoltaic devices, for example, thin film photovoltaic devices such as CIGS photovoltaic devices. These glasses can be characterized as having strain points ?535° C., for example, ?570° C., thermal expansion coefficients of from 8 to 9 ppm/° C., as well as liquidus viscosities in excess of 50,000 poise. As such they are ideally suited for being formed into sheet by the fusion process.

Abstract: A directionally-controlled roll-out elastically deployable solar array structure is disclosed. The structure includes one or more longitudinal elastic roll out booms that may be closed section or open section to allow for efficient rolled packaging onto a lateral mandrel. A flexible photovoltaic blanket is attached to a tip structure and to a lateral base support structure, but remains uncoupled from the longitudinal booms. The solar array system may be stowed simultaneously into a rolled package comprised of the roll out booms and the flexible planar blanket together, or onto independent rolls. Alternatively, the system may be stowed by rolling the booms, and accordion Z-folding the hinged flexible photovoltaic blanket into a flat stack. Structural deployment is motivated by the elastic strain energy of the roll out booms, and several methods of deployment direction control are provided to ensure a known, controlled, and unidirectional deployment path of the elastically unrolling booms.