A solar cell module includes a plurality of compound semiconductor solar cells each including a compound semiconductor substrate, a first electrode part on a front surface of the compound semiconductor substrate, an insulating substrate positioned at a back surface of the compound semiconductor substrate, a second electrode part positioned between the back surface of the compound semiconductor substrate and a front surface of the insulating substrate, and an insulating adhesive attaching the insulating substrate to the second electrode part; a conductive connection member electrically connecting two adjacent compound semiconductor solar cells to each other; a conductive adhesive attaching the conductive connection member to a corresponding electrode part of the compound semiconductor solar cell; a front substrate positioned on the compound semiconductor solar cells; and a back substrate positioned below the compound semiconductor solar cells.

A new type of PV cell is comprised of a purposefully unique spatial configuration of multiple pairs of transparent thin PV films stacked top down in order of decreasing bandgaps corresponding to increasing wavelengths. Each thin-film pair is made of a material of desirable bandgap, and consecutive films separated from each other in space by a layer of air to force confinement of light waves of wavelength matching bandgap, enabling an infinite number of reflections until the wave energy corresponding to each desired wavelength is absorbed. The PV thin-films are coated to ensure that light of each wavelength is confined as intended. They are passivated to minimize surface recombination. This spatial arrangement provides multiple opportunities for photovoltaic conversion of each intended wavelength hence increasing overall conversion efficiency.

According to at least one exemplary embodiment an empyreal reaper may be provided. The empyreal reaper may include a packaging, one or more mirrors contained within the packaging which concentrate photonic energy from a photonic light source into focused light, one or more gain mediums which receive, on one or more absorption faces, the photonic energy concentrated by the one or more mirrors, and/or a photoelectric material which receives photonic energy from the one or more gain mediums and converts the photonic energy into electrical energy.

A system and method for solar energy concentration is provided. One embodiment has a reflective trough with a reflective upper surface that reflects incident sunlight energy towards a focal line; a solar evacuated tube heat collector defined by a transparent fluid container member that has a length that corresponds to a length of the reflective upper surface of the reflective trough, wherein the solar evacuated tube heat collector is located along the focal line associated with the reflective trough such that an interior of the transparent fluid container member encompasses the focal line; and a wave guide located above and in proximity to the solar evacuated tube heat collector having a length corresponding to the length of the solar evacuated tube heat collector, wherein a lower surface of the wave guide has a reflective lower surface that reflects incident sunlight energy downwards onto the solar evacuated tube heat collector.

Disclosed are a solar cell module apparatus and a method of fabricating the same. The solar cell module apparatus includes a light absorbing layer, and a reflector provided on a light incident surface of the light absorbing layer to reflect a light, which has been reflected from the light absorbing layer, toward the light absorbing layer.

A photovoltaic device cell comprising a first light transmissive electrical contact, an active region, a second light transmissive electrical contact, and a layered structure enclosing the active region, the layered structure being formed of two parts, a first part underlying the first light transmissive electrical contact and a second part overlying the second electrical contact and wherein the constants of the layers in these layered structures are interdependent such that light is localized within the active region.

A photovoltaic system consists of a waveguide body, luminescent dyes and a photovoltaic cell. Luminescent dyes and their aggregated particulates with larger diameter are dispersed in the waveguide body to scatter light and transform the first light of the external light into a second light, wherein the wavelength of the second light is longer than the wavelength of the first light. Compared to conventional techniques, the use of luminescent dyes of the present invention can be aggregated into particulates with larger diameter to enhance the power conversion efficiency of the photovoltaic cell, without providing a scattering layer, in order to reduce the production cost and the element complexity of the photovoltaic system. A manufacturing method for a photovoltaic system is also disclosed.

The present disclosure relates to down-shifting nanophosphors, a method for preparing the same, and a luminescent solar concentrator (LSC) using the same. The down-shifting nanophosphors according to an embodiment of the present disclosure include a core including NaYF.sub.4 nanocrystals doped with neodymium (Nd) and ytterbium (Yb), and further include a neodymium (Nd)-doped crystalline shell surrounding the core, or further include a NaYF.sub.4 crystalline shell surrounding the crystalline shell. Therefore, the down-shifting nanophosphors efficiently absorb near infrared rays with a wavelength range of 700-900 nm and efficiently emit near infrared rays with a wavelength range of 950-1050 nm. In addition, the down-shifting nanophosphors according to an embodiment of the present disclosure has a size of 60 nm or less, and thus can be applied to manufacture transparent LSC films with ease and can realize transparent solar cell modules having high near infrared ray shifting efficiency.

A photovoltaic (PV) apparatus includes a substrate having a first substrate surface and a second substrate surface. A cavity fabricated in the substrate extends from the first substrate surface toward the second substrate surface. The cavity defines a first end to receive incident light, a second end opposite the first end, and a side surface, which extends from the first end to the second end to concentrate the incident light, received by the first end, toward the second end. The PV apparatus also includes a photovoltaic (PV) cell, in optical communication with the second end of the at least one cavity, to convert the incident light into electricity.

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.