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.

Wafer alignment with restricted visual access has been disclosed. In an example, a method of processing a substrate for fabricating a solar cell involves supporting the substrate over a stage. The method involves forming a substantially opaque layer over the substrate. The substantially opaque layer at least partially covers edges of the substrate. The method involves performing fit-up of the substantially opaque layer to the substrate. The method involves illuminating the covered edges of the substrate with light transmitted through the stage, and capturing a first image of the covered edges of the substrate based on the light transmitted through the stage. The method further includes determining a first position of the substrate relative to the stage based on the first image of the covered edges. The substrate may be further processed based on the determined first position of the substrate under the substantially opaque layer.

Optically transmissive UV solar cells may be coupled to glass substrates, for example windows, in order to generate electricity while still providing suitable optical behavior for the window. The UV solar cells may be utilized to power electrochromic components coupled to the window to adjust or vary the transmissivity of the window. The UV solar cells may utilize a Schottky ZnO/ZnS heterojunction.

To provide a semiconductor device, a semiconductor laser, and a method of producing a semiconductor device that are capable of sufficiently ensuring electrical connection between a transparent conductive layer and a semiconductor layer. [Solving Means] A semiconductor device according to the present technology includes: a first semiconductor layer; a second semiconductor layer; an active layer; and a transparent conductive layer. The first semiconductor layer has a first conductivity type, a stripe-shaped ridge being formed on a surface of the first semiconductor layer. A second width is not less than 0.99 and not more than 1.0 times a first width, a third width is not less than 0.96 and not more than 1.0 times the second width, and the transparent conductive layer has a uniform thickness within a range of not less than 90% and not more than 110% in a range of the third width, the first width being a width in a direction perpendicular to an extending direction of the ridge on a surface of the ridge on which the transparent conductive layer is formed, the second width being a width in the direction on a surface of the transparent conductive layer on a side of the ridge, the third width being a width in the direction on a surface opposite to the ridge of the transparent conductive layer.

A method is described for selectively depositing a metallic layer (10) including one or more of copper, silver and gold. The method includes depositing a fluorinated layer (5) over a surface (1, 4). The fluorinated layer (5) has a thickness sufficient to substantially prevent deposition of the copper, silver and/or gold between the fluorinated layer (5) and the surface (1, 4) during a subsequent evaporation step using a given deposition rate. The method also includes forming the metallic layer (10) by evaporating, at the given deposition rate, the copper, silver and/or gold over the surface (1, 4) and the fluorinated layer (5). The copper, silver and/or gold preferentially adhere to the portions of the surface (1, 4) not covered by the fluorinated layer (s).

The technique relates to a method for preparing a nanomesh metal membrane 5 transferable on a very wide variety of supports of different types and shapes comprising at least one step of de-alloying 1 a thin layer 6 of a metal alloy deposited on a substrate 7, said method being characterized in that said thin layer 6 has a thickness less than 100 nm, and in that said de-alloying step 1 is carried out by exposing said thin layer 6 to an acid vapor in the gas phase 8, in order to form said nanomesh metal membrane 5.

An extreme and deep ultra-violet photovoltaic device designed to efficiently convert extreme ultra-violet (EUV) and deep ultra violet (DUV) photons originating from an EUV/DUV power source to electrical power via the absorption of photons creating electrons and holes that are subsequently separated via an electric field so as to create a voltage that can drive power in an external circuit. Unlike traditional solar cells, the absorption of the extreme/deep ultra-violet light near the surface of the device requires special structures constructed from large and ultra-large bandgap semiconductors so as to maximize converted power, eliminate absorption losses and provide the needed mechanical integrity.

Wafer alignment with restricted visual access has been disclosed. In an example, a method of processing a substrate for fabricating a solar cell involves supporting the substrate over a stage. The method involves forming a substantially opaque layer over the substrate. The substantially opaque layer at least partially covers edges of the substrate. The method involves performing fit-up of the substantially opaque layer to the substrate. The method involves illuminating the covered edges of the substrate with light transmitted through the stage, and capturing a first image of the covered edges of the substrate based on the light transmitted through the stage. The method further includes determining a first position of the substrate relative to the stage based on the first image of the covered edges. The substrate may be further processed based on the determined first position of the substrate under the substantially opaque layer.

A solar cell of an embodiment includes: a first electrode; a second electrode; a light-absorbing layer interposed between the first electrode and the second electrode; a dot region interposed between the first electrode and the light-absorbing layer, the dot region including dots.

Disclosed are methods of sintering metal nanoparticles and methods of making conductive metal films.