Monolithic multi-throw diode switch structures are described. The monolithic multi-throw diode switches include a hybrid arrangement of diodes with different intrinsic regions. In one example, a method of manufacture of a monolithic multi-throw diode switch includes providing an intrinsic layer on an N-type semiconductor substrate, implanting a first P-type region to a first depth into the intrinsic layer to form a first PIN diode comprising a first effective intrinsic region of a first thickness, implanting a second P-type region to a second depth into the intrinsic layer to form a second PIN diode comprising a second effective intrinsic region of a second thickness, and forming at least one metal layer over the intrinsic layer to electrically couple the first PIN diode to a node between a common port and a first port of the switch.

A solar cell in which performance degradation caused by an alkali component is suppressed. A solar cell is a back-contact solar cell that comprises a semiconductor substrate; a p-type semiconductor layer, and a first electrode layer corresponding thereto, layered sequentially on one part of the rear side of the semiconductor substrate; an n-type semiconductor layer, and a second electrode layer corresponding thereto, layered sequentially on another part of the rear side of the semiconductor substrate. One part of the n-type semiconductor layer lies directly atop one part of the adjacent p-type semiconductor layer. The first electrode layer is separate from the n-type semiconductor layer and covers the p-type semiconductor layer. The second electrode layer covers the entirety of an overlapping portion where the n-type semiconductor layer lies atop the p-type semiconductor layer.

A solar cell in which performance degradation caused by an alkali component is suppressed. A solar cell is a back-contact solar cell that comprises a semiconductor substrate; a p-type semiconductor layer, and a first electrode layer corresponding thereto, layered sequentially on one part of the rear side of the semiconductor substrate; an n-type semiconductor layer, and a second electrode layer corresponding thereto, layered sequentially on another part of the rear side of the semiconductor substrate. One part of the n-type semiconductor layer lies directly atop one part of the adjacent p-type semiconductor layer. The first electrode layer is separate from the n-type semiconductor layer and covers the p-type semiconductor layer. The second electrode layer covers the entirety of an overlapping portion where the n-type semiconductor layer lies atop the p-type semiconductor layer.

A photovoltaic structure includes a substrate; and a plurality of off-axis, doped silicon regions outward of the substrate. The plurality of off-axis, doped silicon regions have an off-axis lattice orientation at a predetermined non-zero angle. A plurality of photovoltaic devices of a first chemistry are located outward of the plurality of off-axis, doped silicon regions. Optionally, a plurality of photovoltaic devices of a second chemistry, different than the first chemistry, are located outward of the substrate and are spaced away from the plurality of off-axis, doped silicon regions.

A photovoltaic structure includes a substrate; and a plurality of off-axis, doped silicon regions outward of the substrate. The plurality of off-axis, doped silicon regions have an off-axis lattice orientation at a predetermined non-zero angle. A plurality of photovoltaic devices of a first chemistry are located outward of the plurality of off-axis, doped silicon regions. Optionally, a plurality of photovoltaic devices of a second chemistry, different than the first chemistry, are located outward of the substrate and are spaced away from the plurality of off-axis, doped silicon regions.

A photovoltaic device with an improved n-type partner and a method for making the same. The device includes: a transparent substrate; a transparent conductive electrode layer disposed on the transparent substrate; an n-type layer of Zn.sub.1-xMg.sub.xO, wherein 0<x≦1, disposed on the transparent conductive electrode layer; a chalcogen absorber layer disposed on the n-type layer; and a conductive layer disposed on the chalcogen absorber layer. The method includes: forming a transparent conductive electrode layer on a transparent substrate; forming an n-type layer of Zn.sub.1-xMg.sub.xO, wherein 0<x≦1, on the transparent conductive electrode layer; forming a chalcogen absorber layer on the n-type layer; forming a conductive layer on the chalcogen absorber layer; and annealing to form the device. Another device having a superstrate configuration with the order of the layers reversed and a method for making the same is provided.

This disclosure provides photovoltaic cells and substrates with three dimensional optical architectures and methods of manufacturing the same. In particular, the disclosure relates to a continuously formed photovoltaic substrate, and to systems, devices, methods and uses for such a product, including the collection of solar energy.

This disclosure provides photovoltaic cells and substrates with three dimensional optical architectures and methods of manufacturing the same. In particular, the disclosure relates to a continuously formed photovoltaic substrate, and to systems, devices, methods and uses for such a product, including the collection of solar energy.

Disclosed is a photovoltaic cell including a first electrode and a second electrode having transparency and disposed facing each other, and a photovoltaic cell layer disposed between the first and second electrodes, and configured to produce electric energy by absorbing a part of incident light, wherein the photovoltaic cell layer includes a plurality of unit cells disposed in a specific distance from each other and formed with a plurality of slits for polarizing the incident light, and a transparent insulator disposed in the plurality of slits.

Disclosed is a photovoltaic cell including a first electrode and a second electrode having transparency and disposed facing each other, and a photovoltaic cell layer disposed between the first and second electrodes, and configured to produce electric energy by absorbing a part of incident light, wherein the photovoltaic cell layer includes a plurality of unit cells disposed in a specific distance from each other and formed with a plurality of slits for polarizing the incident light, and a transparent insulator disposed in the plurality of slits.