Manufacture of multi-junction solar cells, and devices thereof, are disclosed. The architectures are also adapted to provide for a more uniform and consistent fabrication of the solar cell structures, leading to improved yields, greater efficiency, and lower costs. Certain solar cells may be from a different manufacturing process and further include one or more compositional gradients of one or more semiconductor elements in one or more semiconductor layers, resulting in a more optimal solar cell device.

There are provided a method and a device for feeding electric power to a vehicle, etc. installed with a solar photovoltaic power generation panel employing a multi-junction solar cell in a non-contact manner by irradiating light to the solar photovoltaic power generation panel. In the method, light containing a wavelength component absorbed by each of all solar cell layers laminated in a multi-junction solar cell of the vehicle, etc. is projected from a light-projecting device to the light receiving surface of the multi-junction solar cell; and electric power generated by the irradiation of light from the multi-junction solar cell is taken out. The device includes structures for emitting light containing a wavelength component absorbed by each solar cell layer laminated in the multi-junction solar cell, and for irradiating the light to a light receiving surface of the multi-junction solar cell.

There are provided a method and a device for feeding electric power to a vehicle, etc. installed with a solar photovoltaic power generation panel employing a multi-junction solar cell in a non-contact manner by irradiating light to the solar photovoltaic power generation panel. In the method, light containing a wavelength component absorbed by each of all solar cell layers laminated in a multi-junction solar cell of the vehicle, etc. is projected from a light-projecting device to the light receiving surface of the multi-junction solar cell; and electric power generated by the irradiation of light from the multi-junction solar cell is taken out. The device includes structures for emitting light containing a wavelength component absorbed by each solar cell layer laminated in the multi-junction solar cell, and for irradiating the light to a light receiving surface of the multi-junction solar cell.

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.

Visibly transparent photovoltaic devices are disclosed, such as those are transparent to visible light but absorb near-infrared light and/or ultraviolet light. The photovoltaic devices make use of transparent electrodes and near-infrared absorbing visibly transparent photoactive compounds, optical materials, and/or buffer materials.

Multiple semiconductor p-n junctions may be built into a single structure to expand the optical capabilities of a device. For example, multi-junction solar cells have improved efficiencies and thus may be desirable for a variety of reasons. Typically, tunnel junctions have been used to connect the plurality of junctions in a two-terminal, layered structure, wherein the junctions are in series electrically and optically. This approach has a variety of drawbacks that lead to higher cost and complexity. The present disclosure embraces an intermetallic bonded multi-junction solar cell that eliminates the problems associated with tunnel junctions and offers additional improvements, such as, photon recycling, light trapping, and simplicity. The present disclosure can also be used as a substitute for wafer bonding with potential advantages for high solar concentration applications. It can also be used in bonding LED structures to achieve white light and dual color LEDs

Multiple semiconductor p-n junctions may be built into a single structure to expand the optical capabilities of a device. For example, multi-junction solar cells have improved efficiencies and thus may be desirable for a variety of reasons. Typically, tunnel junctions have been used to connect the plurality of junctions in a two-terminal, layered structure, wherein the junctions are in series electrically and optically. This approach has a variety of drawbacks that lead to higher cost and complexity. The present disclosure embraces an intermetallic bonded multi-junction solar cell that eliminates the problems associated with tunnel junctions and offers additional improvements, such as, photon recycling, light trapping, and simplicity. The present disclosure can also be used as a substitute for wafer bonding with potential advantages for high solar concentration applications. It can also be used in bonding LED structures to achieve white light and dual color LEDs

A multijunction solar cell including an upper first solar subcell and having an emitter of p conductivity type with a first band gap, and a base of n conductivity type with a second band gap greater than the first band gap; a second solar subcell having an emitter of p conductivity type with a third band gap, and a base of n conductivity type with a fourth band gap greater than the third band gap; and an intermediate grading interlayer disposed between the first and second subcells and having a graded lattice constant that matches the first subcell on a first side and the second subcell on the second side, and having a fifth band gap that is greater than the second band gap of the first solar subcell.

A multijunction solar cell including an upper first solar subcell and having an emitter of p conductivity type with a first band gap, and a base of n conductivity type with a second band gap greater than the first band gap; a second solar subcell having an emitter of p conductivity type with a third band gap, and a base of n conductivity type with a fourth band gap greater than the third band gap; and an intermediate grading interlayer disposed between the first and second subcells and having a graded lattice constant that matches the first subcell on a first side and the second subcell on the second side, and having a fifth band gap that is greater than the second band gap of the first solar subcell.