A device having a plurality of thin film photovoltaic cells (PV) formed over a passivation layer. The device comprises a plurality of thin film photovoltaic (PV) cells formed over the passivation layer, each PV cell includes at least a lower conducting layer (LCL) and an upper conducting layer (UCL); and a conducting path connecting at least a UCL of a first PV cell to at least a LCL of a second PV cell, wherein at least a first array of PV cells comprised of at least a first portion of the plurality of PV cells is connected by the respective UCL and LCL of each PV cell to provide a first voltage output. In an embodiment the passivation layer is formed over a target integrated circuit (TIC), the TIC having a top surface and a bottom surface.

A solar cell including a sequence of layers of semiconductor material forming a solar cell; a metal contact layer over said sequence of layers; a permanent supporting substrate composed of a carbon fiber reinforced polymer utilizing a conductive polyimide binding resin disposed directly over said metal contact layer and permanently bonding thereto.

Improved methods and apparatus for forming thin-film buffer layers of chalcogenide on a substrate web. Solutions containing the reactants for the buffer layer or layers may be dispensed separately to the substrate web, rather than being mixed prior to their application. The web and/or the dispensed solutions may be heated by a plurality of heating elements.

Disclosed are embodiments of a thin-film photovoltaic technology including a single-junction crystalline silicon solar cell with a photonic-plasmonic back-reflector structure for lightweight, flexible energy conversion applications. The back-reflector enables high absorption for long-wavelength and near-infrared photons via diffraction and light-concentration, implemented by periodic texturing of the bottom-contact layer by nanoimprint lithography. The thin-film crystalline silicon solar cell is implemented in a heterojunction design with amorphous silicon, where plasma enhanced chemical vapor deposition (PECVD) is used for all device layers, including a low-temperature crystalline silicon deposition step. Excimer laser crystallization is used to integrate crystalline and amorphous silicon within a monolithic process, where a thin layer of amorphous silicon is converted to a crystalline silicon seed layer prior to deposition of a crystalline silicon absorber layer via PECVD. The crystalline nature of the absorber layer and the back-reflector enable efficiencies higher than what is achievable in other thin-film silicon devices.

A photovoltaic module (12) ensures a highly durable, integrally bonded sealing of the interior (18) of the tube (16). The photo-voltaic module (12) is easy and cost-effective to produce and the efficiency of the photovoltaic module (12) in relation to the effective area for energy conversion is not compromised or is only negligibly compromised. The photovoltaic module (12) is very low-maintenance and has a long service life. Furthermore, the photovoltaic module (12) can be arranged with respect to a plurality of photovoltaic modules (12) arranged in parallel and can form a solar module formed for example from 20 photovoltaic modules (12).

Methods and systems are provided for a photoconductive thin film of a plurality of Lead Selenide (PbSe) nanostructures arranged on quartz substrates. The photoconductive thin film is synthesized, for example, using a chemical bath deposition, and can include a tunable iodine doping process to select the size and/or shape of the nanostructures. An oxygenation sensitization process at a sufficiently high temperature can increase carrier mobility of the thin film.

A photonic device includes a substrate, a P-type doped component disposed over the substrate, an N-type doped component disposed over the substrate, an optical absorption layer disposed over the substrate, and a charging layer disposed over the substrate. The optical absorption layer is disposed between the P-type doped component and the N-type doped component. The optical absorption layer and the substrate have different material compositions. A charging layer is disposed between the P-type doped component and the N-type doped component. The charging layer has a first side surface that is substantially linear. The first side surface is in direct contact with the optical absorption layer.

The present invention relates to a substrate for a thin film photovoltaic module, characterized in that it is a cementitious product with average surface roughness Ra not higher than 500 nm. The invention also relates to the cementitious product as such, the thin film photovoltaic module comprising it, and a method of moulding both of them.

An organic light emitting diode device can be formed by imprinting a material layer to form an array of non-planar features selected from protrusions and via cavities. The array of non-planar features can be imprinted by moving the material layer under a rolling press or under a rolling die that transfers a pattern thereupon. A layer stack including a transparent electrode layer, an organic light emitting material layer, and a backside electrode layer is formed over the array of non-planar features such that convex sidewalls of the organic light emitting material layer contact concave sidewalls of the backside electrode layer. The layer stack can be encapsulated with a passivation substrate. Additionally or alternatively, an array of convex lenses can be imprinted on a transparent material layer to decrease total internal reflection of an organic light emitting diode device.

A solar cell apparatus according to the embodiment includes a support substrate including a plurality of patterns; a back electrode layer on the support substrate; a light absorbing layer on the back electrode layer; a buffer layer on the light absorbing layer; and a front electrode layer on the buffer layer, wherein the patterns are formed in an undercut structure including a first inner side surface, a second inner side surface and a bottom surface.