Multiple semiconductor p-n junctions may be built into a single structure to expand the optical capabilities of a device. For example, multi-junction solar cells have improved efficiencies and thus may be desirable for a variety of reasons. Typically, tunnel junctions have been used to connect the plurality of junctions in a two-terminal, layered structure, wherein the junctions are in series electrically and optically. This approach has a variety of drawbacks that lead to higher cost and complexity. The present disclosure embraces an intermetallic bonded multi-junction solar cell that eliminates the problems associated with tunnel junctions and offers additional improvements, such as, photon recycling, light trapping, and simplicity. The present disclosure can also be used as a substitute for wafer bonding with potential advantages for high solar concentration applications. It can also be used in bonding LED structures to achieve white light and dual color LEDs

A photosensitive device substrate including a substrate, an active device, and a photosensitive device is provided. The active device and the photosensitive device are disposed on the substrate. The active device has a semiconductor pattern and a gate electrode. The semiconductor pattern is disposed between the substrate and the gate electrode. The photosensitive device is electrically connected to the active device. The photosensitive device has a photoelectric conversion layer and a first electrode and second electrode disposed on two opposite sides of the photoelectric conversion layer. The first electrode is located between the photoelectric conversion layer and the semiconductor pattern, and the material of the first electrode includes a metal oxide.

A solar antenna array may comprise an array of carbon nanotube antennas that may capture and convert sunlight into electrical power. A method for constructing the solar antenna array from a glass top down to aluminum over a plastic bottom such that light passing through the glass top and/or reflected off the aluminum both may be captured by the antennas sandwiched between. Techniques for patterning the glass to further direct the light toward the antennas and techniques for continuous flow fabrication and testing are also described.

A solar battery includes a polymer resin layer on a solar cell and an upper substrate on the polymer resin layer. A pattern is formed in the polymer resin layer.

A solar battery includes a polymer resin layer on a solar cell and an upper substrate on the polymer resin layer. A pattern is formed in the polymer resin layer.

A solar cell is discussed. The solar cell according to an embodiment includes a photoelectric conversion unit including a first conductive type region and a second conductive type region formed on the same side of the photoelectric conversion unit; and an electrode formed on the photoelectric conversion unit and including an adhesive layer formed on the photoelectric conversion unit and an electrode layer formed on the adhesive layer, wherein the adhesive layer has a coefficient of thermal expansion that is greater than a coefficient of thermal expansion of the photoelectric conversion unit and is less than a coefficient of thermal expansion of the electrode layer.

A solar cell is discussed. The solar cell according to an embodiment includes a photoelectric conversion unit including a first conductive type region and a second conductive type region formed on the same side of the photoelectric conversion unit; and an electrode formed on the photoelectric conversion unit and including an adhesive layer formed on the photoelectric conversion unit and an electrode layer formed on the adhesive layer, wherein the adhesive layer has a coefficient of thermal expansion that is greater than a coefficient of thermal expansion of the photoelectric conversion unit and is less than a coefficient of thermal expansion of the electrode layer.

A solar cell and a method for manufacturing the same are discussed. The solar cell includes a substrate of a first conductive type, an emitter region of a second conductive type opposite the first conductive type, the emitter region forming a p-n junction along with the substrate, a passivation layer which is positioned on a back surface of the substrate and has a plurality of via holes exposing portions of the back surface of the substrate, a first electrode connected to the emitter region, and a second electrode which is positioned on a back surface of the passivation layer and is connected to the substrate through the plurality of via holes.

A solar cell and a method for manufacturing the same are discussed. The solar cell includes a substrate of a first conductive type, an emitter region of a second conductive type opposite the first conductive type, the emitter region forming a p-n junction along with the substrate, a passivation layer which is positioned on a back surface of the substrate and has a plurality of via holes exposing portions of the back surface of the substrate, a first electrode connected to the emitter region, and a second electrode which is positioned on a back surface of the passivation layer and is connected to the substrate through the plurality of via holes.

Photovoltaic structures are disclosed. The structures can comprise randomly or periodically structured layers, a dielectric layer to reduce back diffusion of charge carriers, and a metallic layer to reflect photons back towards the absorbing semiconductor layers. This design can increase efficiency of photovoltaic structures. The structures can be fabricated by nanoimprint.