Abstract: The solar tracker comprises a base (1) and a solar panel (2) having first and second opposite ends (2a, 2b). The first end (2a) can be connected to the base (1) by a first shaft (E1) and the second end (2b) can be connected to the base (1) by a second shaft (E2), such that said solar panel (2) can pivot with respect to the base (1) alternately around the first shaft (E1) and around the second shaft (E2) under the drive of a lifting mechanism. An automatic connection/disconnection device connects the second end (2b) of the solar panel (2) to the base (1) while at the same time disconnecting the first end (2a) of the solar panel (2) from the base (1), and vice versa, every time the solar panel (2) reaches a position parallel to the base (1) for inverting the inclination of the solar panel (2) with respect to the base (1).

Abstract: A solar cell system may maximize solar cell efficiency and minimize energy loss by collecting as much light as possible, using refraction and total internal reflection. The solar cell system includes a solar cell, a layer of a first transparent material placed on the top end of the solar cell, a layer of a second transparent material filling the interior cavity of the solar cell, a plurality of photo-voltaic surface cells incorporated in the solar cell, and the side walls and bottom end of the solar cell are coated with a reflective material.

Abstract: A photovoltaic cell can include a nitrogen-containing metal layer in contact with a semiconductor layer.

Abstract: A solar energy module includes a photovoltaic unit including a layer of one or more solar cells. The layer has a front side exposed to incident radiation and an opposite back side. The solar energy module also includes a thermal unit thermally coupled to the back side of the layer of one or more solar cells. The thermal unit includes one or more channels through which a thermal transfer fluid flows, wherein a portion of the incident radiation is converted into electricity by the layer of one or more solar cells and a portion of the incident radiation is simultaneously converted to heat for increasing the temperature of the thermal transfer fluid. The solar energy module also includes a heating system to further increase the temperature of the thermal transfer fluid. The heating system is powered by electricity generated by the one or more solar cells.

Abstract: Nanoplasmonic cavities for photovoltaic applications include at least one transparent conductive substrate. The nanoplasmonic cavities comprising a sandwich of layers incorporating a first plasmonic electrically conductive nanostructure layer, at least one photoabsorber layer and a at least one electron transfer layer and a second plasmonic electrically conductive nanostructure layer.

Abstract: Nanoplasmonic cavities for photovoltaic applications include at least one transparent conductive substrate. A first plasmonic electrically conductive nanostructure layer is associated with the transparent conductive substrate. At least one photoabsorber layer is associated with the first plasmonic electrically conductive nanostructure layer. At least one electron transfer layer is associated with the photoabsorber layer. A second plasmonic electrically conductive nanostructure layer is associated with the electron transfer layer. Multiple nanoplasmonic cavities can be electrically connected to provide greater photovoltaic efficiency.

Abstract: A thermogenerator including several thermocouples that are electrically connected together. The thermocouples are arranged between one hot side of the thermogenerator receiving a thermal flow and a cold side that is arranged at a distance from the hot side. The thermoelectric generator that at least temporarily uses the fed thermal energy efficiently. The thermoelectric generator can be designed as a module including a collector for a thermal solar system and the thermal carrier medium flowing through the collector is guided, at least temporarily, to a thermoelectric generator by a heat exchanger.

Abstract: Photovoltaic devices and techniques for enhancing efficiency thereof are provided. In one aspect, a photovoltaic device is provided. The photovoltaic device comprises a photocell having a photoactive layer and a non-photoactive layer adjacent to the photoactive layer so as to form a heterojunction between the photoactive layer and the non-photoactive layer; and a plurality of high-aspect-ratio nanostructures on one or more surfaces of the photoactive layer. The plurality of high-aspect-ratio nanostructures are configured to act as a scattering media for incident light. The plurality of high-aspect-ratio nanostructures can also be configured to create an optical resonance effect in the incident light.

Abstract: Multi-crystalline group II-VI solar cells and methods for fabrication of same are disclosed herein. A multi-crystalline group II-VI solar cell includes a first photovoltaic sub-cell comprising silicon, a tunnel junction, and a multi-crystalline second photovoltaic sub-cell. A plurality of the multi-crystalline group II-VI solar cells can be interconnected to form low cost, high throughput flat panel, low light concentration, and/or medium light concentration photovoltaic modules or devices.

Abstract: A thermoelectric material includes powders having a surface coated with an inorganic material. The thermoelectric material includes a thermoelectric semiconductor powder and a coating layer on an outer surface of the thermoelectric semiconductor powders.

Abstract: A solar cell and a method for manufacturing the same are disclosed. The solar cell includes a semiconductor layer containing first impurities, a first portion positioned on a first part of one surface of the semiconductor layer, the first portion being more heavily doped with second impurities different from the first impurities than the semiconductor layer, a second portion positioned on a second part of the one surface of the semiconductor layer, the second portion being more heavily doped with the first impurities than the semiconductor layer, and a third portion positioned between the first portion and the second portion, the third portion having an impurity concentration lower than an impurity concentration of the first portion and an impurity concentration of the second portion.

Abstract: Methods and apparatus for converting electromagnetic radiation, such as solar energy, into electric energy with increased efficiency when compared to conventional solar cells are provided. A photovoltaic (PV) device generally includes a window layer; an absorber layer disposed below the window layer such that electrons are generated when photons travel through the window layer and are absorbed by the absorber layer; and a plurality of contacts for external connection coupled to the absorber layer, such that all of the contacts for external connection are disposed below the absorber layer and do not block any of the photons from reaching the absorber layer through the window layer. Locating all the contacts on the back side of the PV device avoids solar shadows caused by front side contacts, typically found in conventional solar cells. Therefore, PV devices described herein with back side contacts may allow for increased efficiency when compared to conventional solar cells.

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. A photovoltaic (PV) unit may have all electrical contacts positioned on the back side of the PV device to avoid shadowing and increase absorption of the photons impinging on the front side of the PV unit. Several PV units may be combined into PV banks, and an array of PV banks may be connected to form a PV module with thin strips of metal or conductive polymer formed at low temperature. Such innovations may allow for greater efficiency and flexibility in PV devices when compared to conventional solar cells.

Abstract: A photoelectric conversion element comprising a substrate, a first electrode, a photoelectric conversion layer comprising a semiconductor and a sensitizing dye, a hole transport layer and a second electrode, wherein the hole transport layer comprises a polymer having a repeat unit represented by Formula (1) or (2),

Abstract: The invention relates to a reflective device for a photovoltaic module formed by a plurality of bifacial photovoltaic cells or rows of said cells spaced apart from one another, each cell having an active front face and an active rear face that can capture photons from incident light rays falling on the front and rear faces. The device comprises at least one reflective module to be placed under the cells substantially in line with the gap(s) separating two adjacent cells or two rows of adjacent cells. The reflective module comprises: a first portion, of which the surfaces that are oriented towards the gap have a first curvature such as to send all or part of the incident photons towards the rear face of the cells; and a second portion mounted on the first portion, of which the surfaces oriented towards the gap have a second curvature such as to send all or part of the incident photons towards the rear face of the cells, the second curvature being different from the first curvature.

Abstract: A photovoltaic device is disclosed. The photovoltaic device includes a substrate, an anode, a cathode, and a semiconducting bilayer. The bilayer is composed of a first continuous sublayer and a second continuous sublayer. The first sublayer includes a first polymorph of a metallophthalocyanine. The second sublayer includes a second polymorph of the same metallophthalocyanine. The complementary absorption profiles of the polymorphs result in a device having greater absorption and efficiency, improving performace of the photovoltaic device.

Abstract: A system, method, and apparatus for a multi sensor solar collection system are disclosed herein. The disclosed method for controlling the disclosed multi sensor solar collection system involves providing a plurality of different sets of solar cells that have different spectral response properties. The method also involves focusing, with at least one focusing element, a light beam on a first set of the solar cells according to a current light condition. Further, the method involves focusing, with at least one focusing element, the light beam on a second set of the solar cells according to a change in the current light condition. In other embodiments, the method involves moving a planar mounting that the solar cells are mounted on to focus the light beam on the second set of solar cells according to the change in the current light condition.

Abstract: Methods and systems are provided for air conditioning, capturing combustion contaminants, desalination, and other processes using liquid desiccants.

Abstract: Provided is a solar battery module wherein solar battery cells are electrically connected to each other by using a wiring board having a predetermined wiring pattern formed on a resin base material. A method for manufacturing such solar battery module is also provided. In the wiring board of the solar battery module, a direction wherein a design margin is small is permitted to be a direction wherein the thermal contraction ratio of the resin base material is small, by the shape of an electrode pattern on the solar battery cell and that of the wiring pattern on the wiring board. At the time of manufacturing such solar battery module, temperature in a heat treatment step is set at 100° C. or higher but not higher than 180° C.

Abstract: A photoelectric cell includes at least one photoelectric conversion module. The photoelectric module includes a first photoelectric conversion element and a second photoelectric conversion element. The first photoelectric conversion element is made of a first thermoelectric material having positive thermoelectric coefficient and comprises a first absorbing part and a first non-absorbing part. The second photoelectric conversion element is made of a second thermoelectric material having negative thermoelectric coefficient and comprises a second absorbing part and a second non-absorbing part. The first absorbing part is electrically connected with the second absorbing part.