Multijunction Solar Cell Substrate

In this three junction imm solar cell high performance subcells are realized by.

Multijunction solar cell substrate.

Multi junction solar cells and methods for making multi junction solar cells are disclosed. The maximum theoretical efficiency that a single bandgap solar cell can achieve with non concentrated sunlight is about 33 5 primarily because of. The device has a very high conversion efficiency of approximately 40 and high open circuit voltage and low series resistance. Outside the core area of electronic devices an eu funded project is showing its great potential as a substrate to lead next generation multi junction solar cells.

Monolithic integration of iii v compound semiconductors on si substrates is of major importance for next generation electronics optoelectronics and photovoltaic devices for energy conversion the successful integration of these lattice mismatched semiconductors would result in a significant cost reduction of multijunction solar cell due to the combined lower cost of. 1 inverting the usual growth order growing mismatched cells last 2 engineering a transparent buffer layer to mitigate dislocations and 3 removing the primary substrate attachment to the secondary handle. High efficiency multijunction devices use multiple bandgaps or junctions that are tuned to absorb a specific region of the solar spectrum to create solar cells having record efficiencies over 45. A promising platform for multi junction solar cells.

A solar cell is disclosed with v grooves which are series connected but electrically isolated indirect bandgap solar cells which are responsive to different light frequencies on both sides of a semi insulating optically transparent substrate. Multi junction mj solar cells are solar cells with multiple p n junctions made of different semiconductor materials each material s p n junction will produce electric current in response to different wavelengths of light the use of multiple semiconducting materials allows the absorbance of a broader range of wavelengths improving the cell s sunlight to electrical energy conversion efficiency. Germanium has long been a popular material for integrated circuits. Solar cells with efficiencies higher than 30 including multijunction iii v cells and iii v cells combined with silicon cells are the best candidates for applications in the automotive sector.

Multijunction solar cells based on iii v materials gallium arsenide gaas aluminum indium phosphide alinp aluminum gallium indium phosphide algainp gallium indium phosphide gainp and indium phosphide inp etc show high efficiency exceeding 35 but due to the high production cost and low availability of their constituents these solar cells are not considered suitable for cost.