Abstract: Corrosion resistant thermoelectric devices and methods of manufacturing them are disclosed herein. In some embodiments, a corrosion resistant thermoelectric device includes a semiconductor layer; a corrosion resistant top metallization layer formed on a top surface of the semiconductor layer; and a corrosion resistant bottom metallization layer formed on a bottom surface of the semiconductor layer, where the bottom surface of the semiconductor layer is opposite of the top surface of the semiconductor layer. In this way, the corrosion resistance of the device is provided by the intrinsic properties of the materials used rather than provided by the packaging or a surface coating. As such, the corrosion protection can be ensured and verified by control of the materials used to construct the device. This approach is also less susceptible to damage from shipment, handling, integration, attachment, and assembly operations because the corrosion protection is intrinsic to the materials used in construction.

Abstract: A solar cell receiver subassembly for use in a concentrating solar system which concentrates the solar energy onto a solar cell by a factor of 1000 or more for converting solar energy to electricity, including an optical element defining an optical channel, a solar cell receiver having a support; a solar cell mounted on the support adjacent to the optical element and in the optical path of the optical channel, the solar cell comprising one or more III-V compound semiconductor layers and capable of generating in excess of 20 watts of peak DC power; a diode mounted on the support and coupled in parallel with the solar cell; and first and second electrical contacts mounted on the support and coupled in parallel with the solar cell and the diode; and an encapsulant covering the support, the solar cell, the diode, and at least a portion of the exterior sides of the optical element.

Abstract: A solar cell receiver subassembly for use in a concentrating solar system which concentrates the solar energy onto a solar cell by a factor of 1000 or more for converting solar energy to electricity, including an optical element defining an optical channel, a solar cell receiver having a support; a solar cell mounted on the support adjacent to the optical element and in the optical path of the optical channel, the solar cell comprising one or more III-V compound semiconductor layers and capable of generating in excess of 20 watts of peak DC power; a diode mounted on the support and coupled in parallel with the solar cell; and first and second electrical contacts mounted on the support and coupled in parallel with the solar cell and the diode; and an encapsulant covering the support, the solar cell, the diode, and at least a portion of the exterior sides of the optical element.

Abstract: According to an embodiment, a solar cell receiver for converting solar energy to electricity includes a ceramic substrate, a solar cell and a heat sink. The ceramic substrate has a first metallized surface and an opposing second metallized surface. The first metallized surface of the ceramic substrate has separated conductive regions. The solar cell has a conductive first surface connected to a first one of the conductive regions of the ceramic substrate and an opposing second surface having a conductive contact area connected to a second one of the conductive regions. The heat sink is bonded to the second metallized surface of the ceramic substrate with a thermally conductive attach media, such as a metal-filled epoxy adhesive or solder.

Abstract: A solar cell receiver for converting solar energy to electricity including a substrate, a III-V compound semiconductor multi-junction solar cell mounted on the substrate, a diode mounted on the substrate, including a body, an anode contact and a cathode contact, the diode coupled in parallel with the solar cell, output terminals mounted on the substrate and coupled to the solar cell and the diode for handling more than 10 watts of power, and at least one spacer and a transparent lid thereover configured to cover and protect the solar cell.