Abstract: Light-electricity conversion devices based on II-VI semiconductor materials are provided. The light-electricity conversion devices are able to cover a wide spectrum range.

Abstract: A donor silicon wafer may be bonded to a substrate and a lamina cleaved from the donor wafer. A photovoltaic cell may be formed from the lamina bonded to the substrate. An intermetal stack is described that is optimized for use in such a cell. The intermetal stack may include a titanium layer in contact with the lamina, which reacts to form titanium silicide, a non-reactive barrier layer to check the silicide reaction, a low-resistance layer, and an adhesion layer to help adhesion to the receiver element.

Abstract: Thin film photovoltaic devices including a thin film stabilization layer between the photovoltaic heterojunction and a back contact are provided. The thin film stabilization layer generally includes cadmium sulfide, but may also include copper and/or other materials. Methods are also provided for forming a thin film photovoltaic device via forming a thin film stabilization layer on a photovoltaic heterojunction (that generally overlies a transparent conductive oxide layer on a transparent substrate) and forming a back contact on the thin film stabilization layer.

Abstract: Certain example embodiments relate to a transparent conductor film stack with cadmium stannate used as a front contact layer and/or a buffer layer in a photovoltaic device or the like. The cadmium stannate-based layers may be provided between the front glass substrate and the semiconductor absorber film in a photovoltaic device (e.g., a CdS and/or CdTe based photovoltaic device). In certain example embodiments, the buffer layer based on cadmium stannate may have a higher resistivity than the transparent conductive oxide layer based on cadmium stannate. In certain example embodiments, one or more index matching layer(s) may be provided between the glass substrate and the layer(s) comprising cadmium stannate, e.g., to help overcome the optical mismatch between the glass substrate and the CdSnOx.

Abstract: A thin film photovoltaic cell (10) comprises an n-type semiconductor window layer (40), a p-type semiconductor absorption layer (5) and a pn-junction (6) at the interface between these two layers, wherein the p-type semiconductor absorption layer is formed of cadmium telluride CdTe. According to the present invention, the n-type semiconductor window layer (40) comprises zinc oxide/sulfide Zn (O,S).

Abstract: Nanostructures and photovoltaic structures are disclosed. A nanostructure according to one embodiment includes an array of nanocables extending from a substrate, the nanocables in the array being characterized as having a spacing and surface texture defined by inner surfaces of voids of a template; an electrically insulating layer extending along the substrate; and at least one layer overlaying the nanocables. A nanostructure according to another embodiment includes a substrate; a portion of a template extending along the substrate, the template being electrically insulative; an array of nanocables extending from the template, portions of the nanocables protruding from the template being characterized as having a spacing, shape and surface texture defined by previously-present inner surfaces of voids of the template; and at least one layer overlaying the nanocables.

Abstract: Thin film photovoltaic devices are generally provided. The device can include a transparent conductive oxide layer on a glass substrate, an n-type thin film layer on the transparent conductive layer, and a p-type thin film layer on the n-type layer. The n-type thin film layer and the p-type thin film layer form a p-n junction. An anisotropic conductive layer is applied on the p-type thin film layer, and includes a polymeric binder and a plurality of conductive particles. A metal contact layer can then be positioned on the anisotropic conductive layer.

Abstract: Certain example embodiments of this invention relate to an electrode (e.g., front electrode) for use in a photovoltaic device or the like. In certain example embodiments, a transparent conductive oxide (TCO) based front electrode for use in a photovoltaic device is of or includes zinc oxide, or zinc aluminum oxide, doped with yttrium (Y). In certain example embodiments, the addition of the yttrium (Y) to the conductive zinc oxide or zinc aluminum oxide is advantageous in that potential conductivity loss of the electrode can be reduced or prevented. In other example embodiments, a low-E coating may include a layer of or including zinc oxide, or zinc aluminum oxide, doped with yttrium (Y).

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

Abstract: Provided is a solar cell module that comprises a solar cell assembly. The solar cell assembly is encapsulated by a poly(vinyl butyral) encapsulant and contains a silver component that is at least partially in contact with the poly(vinyl butyral) encapsulant. The poly(vinyl butyral) encapsulant comprises poly(vinyl butyral), about 15 to about 45 wt % of one or more plasticizers, and about 0.1 to about 2 wt % of one or more unsaturated heterocyclic compounds, based on the total weight of the poly(vinyl butyral) encapsulant. Further provided are an assembly for preparing the solar cell module; a process for preventing or reducing the discoloration of a poly(vinyl butyral) encapsulant in contact with a silver component in the solar cell module; and the use of the solar cell module to convert solar energy to electricity.

Abstract: A method for manufacturing a solar cell including a substrate, a first electrode layer, a semiconductor layer, and a second electrode layer, includes forming a first sacrificial layer on a portion of a surface of the substrate; forming the first electrode layer on the substrate and on the first sacrificial layer; and dividing the first electrode layer by removing the first sacrificial layer and a portion of the first electrode layer formed on the first sacrificial layer.

Abstract: Novel structures of photovoltaic cells (also treated as solar cells) are provided. The cells are based on nanometer-scaled wires, tubes, and/or rods, which are made of electronic materials covering semiconductors, insulators or 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 in space, commercial, residential, and industrial applications.

Abstract: Provided is a transparent color solar cell, which includes a substrate, a first electrode layer disposed on the substrate, a transparent material layer including quantum dots having the same particle size, which absorb visible light provided from the sun through the first electrode layer and having a first wavelength region, and which selectively transmit visible light provided from the sun through the first electrode layer and having a second wavelength region, and a second electrode layer disposed on the transparent material layer.

Abstract: Novel structures of photovoltaic cells (also treated as solar cells) are provided. The Cells are based on the nanometer-scaled wire, tubes, and/or rods, which are made of the electronics materials covering semiconductors, insulator or metallic in structure. These photovoltaic cells have large power generation capability per unit physical area over the conventional cells. These cells can have also high radiation tolerant capability. These cells will have enormous applications such as in space, in commercial, residential and industrial applications.

Abstract: A solar cell including a photovoltaic layer, a first electrode layer, a second electrode layer, an insulating layer and a light-transparent conductive layer is provided. The photovoltaic layer has a first surface and a second surface. The first electrode layer having at least one gap is disposed on the first surface, wherein the at least one gap exposes a portion of the photovoltaic layer. The second electrode layer is disposed on the second surface. The insulating layer having a plurality of pores is located on the photovoltaic layer exposed by the at least one gap, wherein the holes expose a portion of the photovoltaic layer. The light-transparent conductive layer covers the insulating layer and is connected with the first electrode layer. The transparent electrode is connected with the photovoltaic layer through at least a part of the pores. A method of fabricating a solar cell is also provided.

Abstract: A solar cell comprises a substrate configured to have a plurality of via holes and a first conductive type, an emitter layer placed in the substrate and configured to have a second conductive type opposite to the first conductive type, a plurality of first electrodes electrically coupled to the emitter layer, a plurality of current collectors electrically coupled to the first electrodes through the plurality of via holes, and a plurality of second electrodes electrically coupled to the substrate. The plurality of via holes comprises at least two via holes having different angles.

Abstract: One aspect of the present invention provides a device that includes a substrate; a first semiconducting layer; a transparent conductive layer; a transparent window layer. The transparent window layer includes cadmium sulfide and oxygen. The device has a fill factor of greater than about 0.65. Another aspect of the present invention provides a method of making the device.

Abstract: The invention relates to a solar photovoltaic energy conversion apparatus. The apparatus consists of a substrate, a buffer layer formed on the substrate layer, a first transparent conductive oxide layer formed on the buffer layer, periodic protrusions containing first silicon layers formed on the first transparent conductive oxide layer, second silicon layers formed on the first silicon layers, a second transparent conductive oxide layer covering the first silicon layers, the second silicon layers and the first transparent conductive oxide layer, and an anti-reflective protective layer. The first silicon layer and the second silicon layer are the electrodes with the opposite type of charge carriers. The first transparent conductive layer and the second transparent conductive layer are the electrodes with the opposite type of charge carriers. This TCO-based hybrid solar photovoltaic energy conversion device not only can allow the transmission of visible sunlight but also can enhance the photovoltaic energy.

Abstract: In a method of annealing a Cd1-xZnxTe sample/wafer, surface contamination is removed from the sample/wafer and the sample/wafer is then introduced into a chamber. The chamber is evacuated and Hydrogen or Deuterium gas is introduced into the evacuated chamber. The sample/wafer is heated to a suitable annealing temperature in the presence of the Hydrogen or Deuterium gas for a predetermined period of time.

Abstract: The assemblies of the present disclosure comprise an electrode, and a polyimide film. The polyimide film comprises a sub-micron filler and a polyimide. The polyimide is derived from at least one aromatic dianhydride component selected from rigid rod dianhydride, non-rigid rod dianhydride and combinations thereof, and at least one aromatic diamine component selected from rigid rod diamine, non-rigid rod diamine and combinations thereof. The mole ratio of dianhydride to diamine is 48-52:52-48 and the ratio of X:Y is 20-80:80-20 where X is the mole percent of rigid rod dianhydride and rigid rod diamine, and Y is the mole percent of non-rigid rod dianhydride and non-rigid rod diamine. The sub-micron filler is less than 550 nanometers in at least one dimension; has an aspect ratio greater than 3:1; is less than the thickness of the film in all dimensions.

Abstract: A compound thin film solar cell of an embodiment includes: as a light-absorbing layer a semiconductor thin film which contains Cu, an element A (A is at least one element selected from a group consisting of Al, In and Ga) and Te, and has a chalcopyrite crystal structure, wherein a buffer layer that forms an interface with the light-absorbing layer is a compound which contains at least one element selected from Cd, Zn and a group consisting of In and Ga and at least one element selected from a group consisting of S, Se and Te, and has any crystal structure of a sphalerite structure, a wurtzite structure and a defect spinel structure, and a lattice constant “a” of the buffer layer with the sphalerite structure or a lattice constant “a” of the buffer layer at the time of converting the wurtzite structure or the defect spinel structure to the sphalerite structure is not smaller than 0.59 nm and not larger than 0.62 nm.

Abstract: Methods for manufacturing a cadmium telluride based thin film photovoltaic device are generally disclosed. A resistive transparent layer can be sputtered on a transparent conductive oxide layer from a metal alloy target in a sputtering atmosphere of argon and oxygen that includes argon from about 5% to about 40%. A cadmium sulfide layer can then be formed on the resistive transparent layer. A cadmium telluride layer can be formed on the cadmium sulfide layer; and a back contact layer can be formed on the cadmium telluride layer. The sputtering can be accomplished within a sputtering chamber.

Abstract: A cadmium telluride thin film photovoltaic device is provided having a thin film interlayer positioned between a cadmium sulfide layer and a cadmium telluride layer. The thin film interlayer can be an oxide thin film layer (e.g., an amorphous silica layer, a cadmium stannate layer, a zinc stannate layer, etc.) or a nitride film, and can act as a chemical barrier at the p-n junction to inhibit ion diffusion between the layers. The device can include a transparent conductive layer on a glass superstrate, a cadmium sulfide layer on the transparent conductive layer, a thin film interlayer on the cadmium sulfide layer, a cadmium telluride layer on the thin film interlayer, and a back contact on the cadmium telluride layer. Methods are also provided of manufacturing such devices.

Abstract: Cadmium telluride based thin film photovoltaic devices are generally described. The device can include a transparent conductive oxide layer on a substrate. A plurality of metal gridlines can directly contact the transparent conductive oxide layer, and can be oriented in a first direction. A cadmium sulfide layer can be included on the transparent conductive oxide layer, and a cadmium telluride layer can be included on the cadmium sulfide layer. A plurality of scribe lines can be defined through the thickness of the cadmium sulfide layer and the cadmium telluride layer to define a plurality of photovoltaic cells such that the plurality of scribe lines are oriented in a second direction that intersects with the first direction.

Abstract: Thin film photovoltaic devices are provided that generally include a transparent conductive oxide layer on the glass, a multi-layer n-type stack on the transparent conductive oxide layer, and an absorber layer (e.g., a cadmium telluride layer) on the multi-layer n-type stack. The multi-layer n-type stack generally includes a first layer (e.g., a cadmium sulfide layer) and a second layer (e.g., a mixed phase layer). The multi-layer n-type stack can, in certain embodiments, include additional layers (e.g., a third layer, a fourth layer, etc.). Methods are also generally provided for manufacturing such thin film photovoltaic devices.

Abstract: A photovoltaic (PV) device, comprising a PV interband cascade (IC) stage, wherein the IC PV stage comprises an absorption region with a band gap, the absorption region configured to absorb photons, an intraband transport region configured to act as a hole barrier, and an interband tunneling region configured to act as an electron barrier. An IC PV architecture for a photovoltaic device, the IC PV architecture comprising an absorption region, an intraband transport region coupled to the absorption region, and an interband tunneling region coupled to the intraband transport region and to the adjacent absorption region, wherein the absorption region, the intraband transport region, and the interband tunneling region are positioned such that electrons will flow from the absorption region to the intraband transport region to the interband tunneling region.

Abstract: A method of forming an ohmic contact and electron reflector on a surface of a CdTe containing compound film as may be found, for example in a photovoltaic cell. The method comprises forming a Cd-deficient, Te-rich surface region at a surface of the CdTe containing compound film; exposing the Cd-deficient surface region to an electron reflector forming material; forming the electron reflector; and laying down a contact layer over the electron reflector layer. The solar cell so produced has a Cd-deficient region which is converted to an electron reflector layer on the surface of a CdTe absorber layer, and an ohmic contact. A Cd/Te molar ratio within the Cd-deficient region decreases from 1 at an interface with the CdTe absorber layer to a value less than 1 towards the ohmic contact.

Abstract: A conversion solar cell structure responds to a greater portion of the solar spectrum. The solar-cell structure has a solar cell and a conversion material disposed over the solar cell.

Abstract: Extremely high efficiency solar cells are described. Novel alternating bias schemes enhance the photovoltaic power extraction capability above the cell band-gap by enabling the extraction of hot carriers. In conventional solar cells, this alternating bias scheme has the potential of more than doubling their yielded net efficiency. In solar cells incorporating quantum wells (QWs) or quantum dots (QDs), the alternating bias scheme has the potential of extending such solar cell power extraction coverage, possibly across the entire solar spectrum, thus enabling unprecedented solar power extraction efficiency. Within such cells, a novel alternating bias scheme extends the cell energy conversion capability above the cell material band-gap while the quantum confinement structures are used to extend the cell energy conversion capability below the cell band-gap.

Abstract: Methods for laser scribing a film stack including a plurality of thin film layers on a substrate are provided. A pulse of a laser beam is applied to the film stack, where the laser beam has a power that varies as a function of time during the pulse according to a predetermined power cycle. For example, the pulse can have a pulse lasting about 0.1 nanoseconds to about 500 nanoseconds. This pulse of the laser beam can be repeated across the film stack to form a scribe line through at least one of the thin film layers on the substrate. Such methods are particularly useful in laser scribing a cadmium telluride thin-film based photovoltaic device.

Abstract: In general, a photovoltaic module may include a binary semiconductor layer formed from a vapor rich in one component of a binary semiconductor source.

Abstract: This invention relates to a front electrode/contact for use in an electronic device such as a photovoltaic device. In certain example embodiments, the front electrode of a photovoltaic device or the like includes a multilayer coating including at least one transparent conductive oxide (TCO) layer (e.g., of or including a material such as tin oxide, ITO, zinc oxide, or the like) and/or at least one conductive substantially metallic IR reflecting layer (e.g., based on silver, gold, or the like). In certain example instances, the multilayer front electrode coating may include one or more conductive metal(s) oxide layer(s) and one or more conductive substantially metallic IR reflecting layer(s) in order to provide for reduced visible light reflection, increased conductivity, cheaper manufacturability, and/or increased infrared (IR) reflection capability. At least one of the surfaces of the front glass substrate may be textured in certain example embodiments of this invention.

Abstract: Methods and devices are provided for absorber layers formed on foil substrate. In one embodiment, a method of manufacturing photovoltaic devices may be comprised of providing a substrate comprising of at least one electrically conductive aluminum foil substrate, at least one electrically conductive diffusion barrier layer, and at least one electrically conductive electrode layer above the diffusion barrier layer. The diffusion barrier layer may prevent chemical interaction between the aluminum foil substrate and the electrode layer. An absorber layer may be formed on the substrate. In one embodiment, the absorber layer may be a non-silicon absorber layer. In another embodiment, the absorber layer may be an amorphous silicon (doped or undoped) absorber layer. Optionally, the absorber layer may be based on organic and/or inorganic materials.

Abstract: A photovoltaic cell can include a transparent conductive layer including cadmium stannate.

Abstract: The present invention relates to a photovoltaic cell, a method of manufacturing such photovoltaic cell, and to uses of such cell.

Abstract: A thin-film solar cell and a manufacturing method thereof are disclosed. The method of manufacturing the thin-film solar cell includes the steps of providing a substrate; forming a diffusion barrier layer on the substrate; forming a back electrode layer on the diffusion barrier layer; forming a precursor layer on the back electrode layer, and the precursor layer including at least Cu, In and Ga; providing an alkali layer on an upper surface of the precursor layer, and the alkali layer being formed of Li, Na, K, Rb, Cs, or an alkali metal compound; providing a selenization process for the precursor layer and the alkali layer to form an absorber layer, such that an atomic percentage concentration of the alkali metal in the absorber layer is ranged between 0.01%˜10%; forming at least a buffer layer on the absorber layer; and forming at least a front electrode layer on the buffer layer.

Abstract: A thin film solar cell includes a buffer layer disposed between a transparent conductive layer and a junction partner layer. The solar cell has an absorber layer made from a Group II-VI compound which is in contact with the junction partner layer. The buffer layer is made from at least one of cadmium doped tin oxide, indium sulfide, tin doped indium sulfide, gallium sulfide and tin doped gallium sulfide.

Abstract: A compositional range of high strain point alkali metal free, silicate, aluminosilicate and boroaluminosilicate glasses are described herein. The glasses can be used as substrates for photovoltaic devices, for example, thin film photovoltaic devices such as CIGS photovoltaic devices. These glasses can be characterized as having strain points ?570° C., thermal expansion coefficient of from 5 to 9 ppm/° C.

Abstract: Thin film photovoltaic devices are provided that generally include a transparent conductive oxide layer on the glass, a multi-layer n-type stack on the transparent conductive oxide layer, and a cadmium telluride layer on the multi-layer n-type stack. The multi-layer n-type stack generally includes a first layer and a second layer, where the first layer comprises cadmium and sulfur and the second layer comprises cadmium and oxygen. The multi-layer n-type stack can, in certain embodiments, include additional layers (e.g., a third layer, a fourth layer, etc.). Methods are also generally provided for manufacturing such thin film photovoltaic devices.

Abstract: The invention provides new methods and compositions for synthesizing hydrogen fuel using simple and inexpensive materials.

Abstract: Disclosed is a device comprising: an anode; a cathode; an inorganic substrate; and at least one organic window layer positioned between: the anode and the inorganic substrate; or the cathode and the inorganic substrate. Also disclosed is a method of enhancing the performance of a photosensitive device having an anode, a cathode, and an inorganic substrate, comprising: positioning at least one organic window layer between the anode and the cathode. In one embodiment the organic window layer may absorb light and generate excitons that migrate to the inorganic where they convert to photocurrent, thereby increasing the efficiency of the device. Also disclosed is a method of enhancing Schottky barrier height of a photosensitive device, the method being substantially similar to the previously defined method.

Abstract: A coating of a photovoltaic device can include a self-assembled monolayer of molecules.

Abstract: Methods of and apparatuses for making a photovoltaic cell are provided. The photovoltaic cell is able to have a substrate made of a composite material. The composite material is able to be formed by mixing a binder and a physical property enhancing material to form a mixer. The binder is able to be pitch, such as mesophase pitch. The physical property enhancing material is able to be fiber glass. The substrate of the photovoltaic cell is able to be flexible, such that the photovoltaic cell is able to be applied on various surfaces.

Abstract: CdSe-quantum dots are formed on a TiO2 patterned layer by chemical deposition from a solution of aminotriacetic acid/cadmium (NTA/Cd) and sodium selenosulfate. CdSe-quantum dots are useful as sensitizers for solar cells. The conversion efficiency of light of light power to electric power is enhanced by adjusting the ratio of potassium aminotriacetate to cadmium (NTA/Cd) as well as the chemical bath deposition (CBD) temperature and time.

Abstract: A flexible solar cell is assembled by forming a TiO2 patterned layer on a flexible substrate electrode. Quantum dots (QDs) are formed on the TiO2 patterned layer. A gasket is disposed between the flexible substrate electrode and a flexible counter electrode forming a sandwich. Electrolyte and sealant are injected between the substrate electrode and flexible counter electrode to form the flexible solar cell.

Abstract: Certain example embodiments relate to a transparent conductor film stack with cadmium stannate used as a front contact layer and/or a buffer layer in a photovoltaic device or the like. The cadmium stannate-based layers may be provided between the front glass substrate and the semiconductor absorber film in a photovoltaic device (e.g., a CdS and/or CdTe based photovoltaic device). In certain example embodiments, the buffer layer based on cadmium stannate may have a higher resistivity than the transparent conductive oxide layer based on cadmium stannate. In certain example embodiments, one or more index matching layer(s) may be provided between the glass substrate and the layer(s) comprising cadmium stannate, e.g., to help overcome the optical mismatch between the glass substrate and the CdSnOx.

Abstract: The present invention provides a solar cell sealing film having enhanced transparency. A composition for a solar cell sealing film contains an ethylene-polar monomer copolymer, a crosslinker and a compound having an alkyleneoxy group. Thereby a solar cell sealing film having excellent all light beam transmittance and enhanced transparency can be formed.

Abstract: The invention relates to a composite structure comprising a photovoltaic cell adhering to an injected polymer (1), in which the photovoltaic cell exhibits an active face (2) adhering to a base (3), characterized in that the photovoltaic cell is continuous and its face directed away from the injected polymer (1) is caused to adhere to an encapsulating polymer (4) with a linear thermal expansion coefficient which does not differ by more than 65% from that of the injected polymer (1) and with a minimum melting point which allows it to withstand the injection of the latter and which promotes adhesion to the injected polymer (1), or in that the photovoltaic cell is openwork; a simple or multiple and monolithic or laminated window comprising such a structure.

Abstract: Extremely high efficiency solar cells are described. Novel alternating bias schemes enhance the photovoltaic power extraction capability above the cell band-gap by enabling the extraction of hot carriers. In conventional solar cells, this alternating bias scheme has the potential of more than doubling their yielded net efficiency. In solar cells incorporating quantum wells (QWs) or quantum dots (QDs), the alternating bias scheme has the potential of extending such solar cell power extraction coverage, possibly across the entire solar spectrum, thus enabling unprecedented solar power extraction efficiency. Within such cells, a novel alternating bias scheme extends the cell energy conversion capability above the cell material band-gap while the quantum confinement structures are used to extend the cell energy conversion capability below the cell band-gap.

Abstract: Methods for manufacturing a cadmium telluride based thin film photovoltaic device are generally disclosed. The method can include sputtering a resistive transparent layer on a transparent conductive oxide layer from an alloy target including zinc from about 5% by weight and about 33% by weight and tin. The method can also include forming a cadmium sulfide layer on the resistive transparent layer, forming a cadmium telluride layer on the cadmium sulfide layer, and forming a back contact layer on the cadmium telluride layer. Cadmium telluride thin film photovoltaic devices are also generally disclosed including a resistive transparent layer having a mixture of zinc oxide and tin oxide having a zinc oxide concentration between about 5% and about 33% by mole fraction.