In one respect, disclosed is a device or system for solar irradiance measurement comprising at least two irradiance sensors deployed outdoors at substantially different angles, such that, by analysis of readings from said irradiance sensors, a direct irradiance, a diffuse irradiance, a global irradiance, and/or a ground-reflected irradiance are determined. In some embodiments the disclosed device or system is stationary and has no moving parts.

According to an embodiment, a photoelectric conversion element includes a photoelectric conversion layer that converts light to charges. The photoelectric conversion layer contains oligothiophene and fullerene selected from a group including a fullerene and derivatives thereof. A content ratio of the oligothiophene and the fullerene is 500:1 to 5:1 by weight.

According to an embodiment, a photoelectric conversion element includes a photoelectric conversion layer that converts light to charges. The photoelectric conversion layer contains oligothiophene and fullerene selected from a group including a fullerene and derivatives thereof. A content ratio of the oligothiophene and the fullerene is 500:1 to 5:1 by weight.

A method of manufacturing a semiconductor device includes providing a substrate structure. The substrate structure includes a conductive layer and a plurality of nanopillars spaced apart from each other overlying the conductive layer. Each nanopillar includes a first semiconductor layer and a second semiconductor layer on the first semiconductor layer. The first semiconductor layer and the second semiconductor layer have different conductivity types. The method also includes forming a graphene layer overlying the plurality of nanopillars. The graphene layer is connected to each of the plurality of nanopillars.

A method of manufacturing a semiconductor device includes providing a substrate structure. The substrate structure includes a conductive layer and a plurality of nanopillars spaced apart from each other overlying the conductive layer. Each nanopillar includes a first semiconductor layer and a second semiconductor layer on the first semiconductor layer. The first semiconductor layer and the second semiconductor layer have different conductivity types. The method also includes forming a graphene layer overlying the plurality of nanopillars. The graphene layer is connected to each of the plurality of nanopillars.

A photovoltaic device includes an organic semiconductor and an inorganic semiconductor. The organic semiconductor includes a photoactive region that generates excitons. The inorganic semiconductor has piezoelectricity and includes a dissociation region for dissociating carriers included in the excitons. A relationship of energy levels between the photoactive region and the dissociation region satisfies at least one equation E.sub.LUMO>E.sub.C or equation E.sub.HOMO<E.sub.V.

A photovoltaic device includes an organic semiconductor and an inorganic semiconductor. The organic semiconductor includes a photoactive region that generates excitons. The inorganic semiconductor has piezoelectricity and includes a dissociation region for dissociating carriers included in the excitons. A relationship of energy levels between the photoactive region and the dissociation region satisfies at least one equation E.sub.LUMO>E.sub.C or equation E.sub.HOMO<E.sub.V.

An apparatus (10) and method for the co-production of high temperature thermal energy and electrical energy from solar irradiance includes a photovoltaic cell (30) laminated to a metal extrusion device (40) and a transparent channel (20) in front of the photovoltaic cell (30). The transparent channel (20) contains a heat transfer fluid that is seeded with metallic, semiconducting, and/or non-metallic nanoparticles and absorbs wavelengths of solar energy that are not utilized or underutilized by the photovoltaic cell (30).

An apparatus (10) and method for the co-production of high temperature thermal energy and electrical energy from solar irradiance includes a photovoltaic cell (30) laminated to a metal extrusion device (40) and a transparent channel (20) in front of the photovoltaic cell (30). The transparent channel (20) contains a heat transfer fluid that is seeded with metallic, semiconducting, and/or non-metallic nanoparticles and absorbs wavelengths of solar energy that are not utilized or underutilized by the photovoltaic cell (30).

Spectral tuning of heat source to emit radiation at a desired frequency or frequency band is accomplished using metamaterials. The metamaterials include a structured geometry having holes with dimensions and spacing chosen such that the resulting surface will emit radiation in the desired spectrum. A collector can be made of a similar metamaterial or antenna array to detect the emitted radiation and transfer it to a converter device that converts the detected radiation to electricity. Embodiments also provide efficient coupling to the converter device for energy harvesting. Cooling of the converter devices can be accomplished using a cooling sink or deep space.