A method includes forming, on a substrate by performing physical vapor deposition in vacuum, an absorber layer including copper (Cu), indium (In), gallium (Ga) and selenium (Se), forming a stack including the substrate and an oxygen-annealed absorber layer by performing in-situ oxygen annealing of the absorber layer to improve quantum efficiency of the image sensor by passivating selenium vacancies due to dangling bonds, and forming a cap layer over the oxygen-annealed absorber layer by performing physical vapor deposition in vacuum. The cap layer includes at least one of: Ga.sub.2O.sub.3.Math.Sn, ZnS, CdS, CdSe, ZnO, ZnSe, ZnIn.sub.2Se.sub.4, CuGaS.sub.2, In.sub.2S.sub.3, MgO, or Zn.sub.0.8Mg.sub.0.2O.

A solar power transmission system having a solar-microwave fabric for absorbing sunlight, transforming the sunlight into electrical energy, amplifying a received signal using the electrical energy, and transmitting the amplified signal to a rectenna beacon. Embodiments according to the present invention include a system for space-based solar power transmission having a solar power collection balloon in geostationary orbit around Earth, which allows for continuous, feasible, and efficient collection of solar power in space that can be packaged into a condensed canister for launch and deployed without manual or machine assembly once in orbit.

Methods and systems are disclosed for processing a precursor material. The method includes introducing a substrate having a precursor material deposited on a surface of the substrate into a first zone of a vacuum chamber. The precursor material comprises copper, indium, and at least one of gallium, selenium, sulfur, sodium, antimony, boron, aluminum, and silver. The method further includes, within the first zone, heating the precursor material to a target reaction temperature within a range of about 270 C. to about 490 C. The method further includes maintaining a selenium vapor in a second zone of the vacuum chamber, and after heating the precursor material to the target reaction temperature, introducing the precursor material and the substrate to the second zone of the vacuum chamber.

A method for forming a wet-etchable, sacrificial lift-off layer or layers compatible with high temperature processing, a sacrificial layer, defined as consisting of a single film of one material or multiple films of multiple materials, that can tolerate high temperatures, is deposited on a substrate, called the original substrate, by sputtering or another suitable technique (e.g. evaporation, pulsed laser deposition, wet chemistry, etc.). Intermediate steps result in a lift-off layer attached to the lift-off substrate, that allow for separating the product from the original substrate.

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 methods and systems for forming a layer on a web with reduced levels of particulates. The layer is formed from a fluid mixture(s) or solution of chemical reagents that react to form the layer. The system includes a conveyor device provided configured to carry the web within the chamber while the first surface of the web undergoes one or more processing steps; a first fluid delivery apparatus and a second fluid delivery apparatus, and a first fluid removal apparatus. The first fluid removal apparatus is positioned within a space arranged between the first and the second delivery apparatuses.

The present invention relates to an exclusive alloy substrate material for CIGS solar cells. Particularly, the present invention provides a substrate material having a thermal expansion coefficient similar to that of a CIGS layer. The substrate material according to the present invention may prevent damage such as interlayer separation due to differing thermal expansion coefficients from occurring because the substrate material has a thermal expansion coefficient similar to that of the CIGS layer.

Improved methods and apparatus for forming thin film layers of chalcogenide on a substrate web. According to the present teachings, a feedback control system may be employed to measure one or more properties of the web and/or the chalcogenide layer, and to adjust one or more parameters of the system or buffer layer deposition method in response to the measurement.

A method for depositing one or more thin-film layers on a flexible polyimide substrate having opposing front and back outer surfaces includes the following steps: (a) heating the flexible polyimide substrate such that a temperature of the front outer surface of the flexible polyimide substrate is higher than a temperature of the back outer surface of the flexible polyimide substrate, and (b) depositing the one or more thin-film layers on the front outer surface of the flexible polyimide substrate. A deposition zone for executing the method includes (a) one of more physical vapor deposition sources adapted to deposit one or more metallic materials on the front outer surface of the substrate, and (b) one or more radiant zone boundary heaters.

Thin-film photovoltaic devices and methods of their use and manufacture are disclosed. More particularly, polycrystalline CuIn.sub.(1-x)Ga.sub.xSe.sub.2 (CIGS) based thin-film photovoltaic devices having independently tunable sublayers are disclosed. Also provided are methods of producing an n-doped graphene.