Photovoltaic systems and methods for optimizing the harvesting of solar energy are disclosed. A photovoltaic (PV) system includes: a solar panel module. The solar panel module comprises: a plurality of solar cell arrays, wherein each array comprises a grouping of solar cells; and a tubular panel. The plurality of solar cell arrays are arranged along an inside surface of the panel. At least an upper portion of the panel slopes inward such that the panel has a substantially funnel-shaped geometry. The solar cell arrays are arranged in a C-ring pattern. A first solar cell array is separated from a second solar cell array by a predetermined distance. The area between the solar cell arrays is coated with a reflective material to facilitate optimal reflection of incident sunlight back to the solar cells. Recycling of incident light is facilitated within the tube. The light can be intermittently or continuously recycled.

A nanoparticle coater includes a housing; a nanoparticle discharge slot; a first combustion slot; and a second combustion slot.

A float bath coating system includes at least one nanoparticle coater located in a float bath. The at least one nanoparticle coater includes a housing, a nanoparticle discharge slot, a first combustion slot, and a second combustion slot. The nanoparticle discharge slot is connected to a nanoparticle source and a carrier fluid source. The first combustion slot is connected to a fuel source and an oxidizer source. The second combustion slot is connected to a fuel source and an oxidizer source.

A glass drawdown coating system includes a container defining a glass ribbon path having a first side and a second side. At least one nanoparticle coater is located adjacent the first side and/or the second side of the glass ribbon path.

A glass article includes a glass substrate having a first surface, a second surface, and an edge. At least one nanoparticle region is located adjacent at least one of the first surface and the second surface.

A three-dimensional thin-film semiconductor substrate with selective through-holes is provided. The substrate having an inverted pyramidal structure comprising selectively formed through-holes positioned between the front and back lateral surface planes of the semiconductor substrate to form a partially transparent three-dimensional thin-film semiconductor substrate.

A light trapping optical cover employing an optically transparent layer with a plurality of light deflecting elements. The transparent layer is configured for an unimpeded light passage through its body and has a broad light input surface and an opposing broad light output surface. The light deflecting elements deflect light incident into the transparent layer at a sufficiently high bend angle with respect to a surface normal and direct the deflected light toward a light harvesting device adjacent to the light output surface. The deflected light is retained by means of at least TIR in the system formed by the optical cover and the light harvesting device which allows for longer light propagation paths through the photoabsorptive layer of the device and for an improved light absorption. The optical cover may further employ a focusing array of light collectors being pairwise associated with the respective light deflecting elements.

A thin film organic photovoltaic device or solar cell in one embodiment includes an organic active bilayer and an ultrathin two-dimensional metallic nanogrid as a transparent conducting electrode which receives incident light. The nanogrid excites surface plasmonic resonances at an interface between the nanogrid and active bilayer from the incident light to enhance photon absorption in the active bilayer below the nanogrid. In another embodiment, spatially separated nanograting electrodes may alternatively be formed by double one-dimensional nanogratings disposed on opposite sides of the organic active bilayer. The spatially separated nanogratings may be oriented perpendicular to each other.

Methods for producing photovoltaic material and a device able to exploit high energy photons. The photovoltaic material is obtained from a conventional photovoltaic material having a top surface intended to be exposed to photonic radiation, having a built-in P-N junction delimiting an emitter part and a base part and including at least one area or region specifically designed, treated or adapted to absorb high energy or energetic photons, located adjacent or near at least one hetero-interface. This material is subjected to treatments resulting in the formation of at least one semiconductor based metamaterial field or region being created, as a transitional region of the or a hetero-interface, in an area located continuous or proximate to the or an absorption area or region for the energetic photons of the photonic radiation impacting the photovoltaic material.

One or more solar cells arranged on a mounting surface along a first direction and extending out from the mounting surface in a second direction that is substantially perpendicular to the first direction. One or more angled reflectors may be arranged on the mounting surface along the first direction. The one or more angled reflectors may include a lens in a wedge shape having: an entrance surface extending along the first direction including a plurality of curved surfaces a bottom surface extending along the second direction and adjacent to the corresponding solar cell of the one or more solar cells, and a reflector surface extending along the second direction at an angle. The reflector surface may include a gradient texture comprising one or more flat surfaces, each of which is substantially parallel to the first direction, and one or more angled elevation surfaces.