A solar cell module includes: a light-diffusing member adjacent to a solar cell; a tab line disposed on front surfaces of solar cells and having a light-diffusing shape on a light-entering side; and a protective member having first and second principal surfaces. When an average distance between a front surface of the solar cell and the second principal surface is expressed as D, a refractive index of the protective member is expressed as n, and a critical angle for total reflection satisfying sin R=1/n is expressed as R, the tab line is disposed in a zone other than a zone between a position at a distance of 3.46×D from, among ends of the light-diffusing member, an end closest to the solar cell and a position at a distance of 2×D×tan R from, among the ends, an end farthest from the solar cell.

The invention relates to a method of making hybrid organic-inorganic core-shell nano-particles, comprising the steps of a) providing colloidal organic particles comprising a synthetic polyampholyte as a template; b) adding at least one inorganic oxide precursor; and c) forming a shell layer from the precursor on the template to result in core-shell nano-particles. With this method it is possible to make colloidal organic template particles having an average particle size in the range of 10 to 300 nm; which size can be controlled by the comonomer composition of the polyampholyte, and/or by selecting dispersion conditions.

The invention also relates to organic-inorganic or hollow-inorganic core-shell nano-particles obtained with this method, to compositions comprising such nano-particles, to different uses of said nano-particles and compositions, and to products comprising or made from said nano-particles and compositions, including anti-reflective coatings and composite materials.

The invention relates to the use in a photovoltaic module of a monolayer film as a backsheet, this composition comprising, with respect to the total weight of the composition from 50 to 100% of amorphous copolyester. The invention further comprises a backsheet of the amorphous copolyester film with two optional films adhered to it, an adhesion promoting film and an anti-weathering film. The invention further encompasses a photovoltaic module comprising the backsheet composition, and an optional scrim layer, according to the invention.

A solar cell, and methods of fabricating said solar cell, are disclosed. The solar cell can include a substrate having a light-receiving surface and a back surface. The solar cell can include a first semiconductor region of a first conductivity type disposed on a first dielectric layer, wherein the first dielectric layer is disposed on the substrate. The solar cell can also include a second semiconductor region of a second, different, conductivity type disposed on a second dielectric layer, where a portion of the second thin dielectric layer is disposed between the first and second semiconductor regions. The solar cell can include a third dielectric layer disposed on the second semiconductor region. The solar cell can include a first conductive contact disposed over the first semiconductor region but not the third dielectric layer. The solar cell can include a second conductive contact disposed over the second semiconductor region, where the second conductive contact is disposed over the third dielectric layer and second semiconductor region. In an embodiment, the third dielectric layer can be a dopant layer.

Photovoltaic (PV) device comprising an ultra-thin radiation-tolerant PV absorber mounted on a flexible film having an embedded persistent phosphor and having a plurality of interdigitated top and bottom contacts on the top of the PV absorber. The PV absorber is ultra-thin, e.g., typically having a thickness of 300 nm or less for a III-V-based absorber. The phosphor absorbs some of the photons incident on the device and then discharges them for use by the device in generating electrical power during times when the device is not illuminated by the sun.

There is provided a capacitive coupled electodeless plasma apparatus for processing a silicon substrate. The apparatus includes at least one inductive antenna driven by time-varying power sources for providing at least one electrostatic field; and a chamber for locating the silicon substrate. There is also provided a method for processing a silicon substrate using capacitively coupled electrodeless plasma.

A low-reflection-loss low-angle-sensitive colored photovoltaic (PV) module is described. This colored PV module includes a transparent substrate; an array of solar cells encapsulated between a top encapsulation sheet and a bottom encapsulation sheet; and a color filter structure embedded between the top encapsulation sheet and the transparent substrate and configured to cause wavelength-selective reflections of incident light received by the colored PV module. Moreover, the transparent substrate includes a flat front surface configured to receive the incident light and a texture back surface configured with an array of features. The color filter structure is formed on the textured back surface of the transparent substrate to create a textured interface between the textured back surface and the color filter structure.

A method of fabricating submicron textures on glass and transparent conductors includes depositing a plurality of silica or silica-coated polystyrene nanospheres onto a substrate, etching the silica coated polystyrene nanospheres and the substrate to form a plurality of nanocone projections on a first side of the substrate, and depositing a transparent conducting oxide onto the substrate on top of the nanocone projections.

Roll-to-roll fabrication of predetermined or ordered three-dimensional nanostructure arrays is described. Provided methods can comprise imprinting a substrate with a two-dimensional (2-D) pattern by rolling a cylindrical pattern comprising a 2-D array of structures against a substrate. In addition, control or determination of nanostructure parameters via control of process parameters is provided.

A method for manufacturing a photovoltaic device capable of suppressing decreases in an open-circuit voltage and a fill factor or suppressing the occurrence of a current leak. The method for manufacturing a photovoltaic device includes: (a) forming a pyramidal texture on a first main surface of a silicon substrate; (b) forming a first silicate glass on the first main surface; (c) forming a second silicate glass on the first silicate glass; (d) diffusing the impurities of the first conductivity type contained in the first silicate glass to the first main surface of the silicon substrate; (e) forming a third silicate glass on the second silicate glass; and (f) diffusing impurities of a second conductivity type to a second main surface of the silicon substrate after (e).