11 Projects Funded for High-Performance Solar Power

Today in Las Vegas, President Obama and Energy Secretary Moniz announced at the Clean Energy Summit $24 million in innovation funding for 11 new solar technologies, as part of ARPA-E’s newest program, MOSAIC. Short for Micro-scale Optimized Solar-cell Arrays with Integrated Concentration, MOSAIC projects seek to develop a new class of cost-effective, high-performance solar energy modules.

ARPA-E Director Dr. Ellen D. Williams responded to the announcement, stating “The MOSAIC program demonstrates ARPA-E’s novel approach to energy innovation. By bringing together cutting edge advances in micro-fabrication, materials science and mechanical actuation, MOSAIC will create new options for solar generation and help make clean energy technologies even more affordable.”

MOSAIC aims to develop new solar modules with the high performance of concentrated photovoltaic (CPV) technologies, but at a cost and profile similar to commonly used flat-plate PV. Although CPV is much more efficient than flat-plate PV, CPV has not been widely adopted due to its high cost, large size and expensive solar tracking systems. MOSAIC project teams will address these limitations by designing micro-scale CPV systems that can be integrated into flat-plate solar panels. These micro-CPV technologies will use thousands of small lenses to concentrate sunlight onto an array of micro-PV cells in order to achieve a higher solar-to-electricity conversion. By exploiting micro-CPV techniques, the teams aim to reduce system costs and dramatically improve flat-plate PV efficiency – and thereby expand the market and geographic areas in which these technologies can operate successfully.

Additional information on ARPA-E’s MOSAIC program can be found HERE. Details on the 11 MOSAIC projects can be found HERE.

To view the White House release, click HERE. To view the Energy Department’s announcement, click HERE.

Example of a selected MOSAIC project:

Semprius, Inc. | Durham, NC | Micro-Scale Ultra-High Efficiency CPV/Diffuse Hybrid Arrays Using Transfer Printing

Semprius and its partners will design a CPV module that integrates two types of solar cells in order to efficiently capture diffuse and direct sunlight. The team will create six-junction PV cells that exceed the efficiency of even the highest performing PV cells on the market today. Arrays of these six-junction PV cells will convert direct sunlight to electricity, while low-cost single-junction solar cells will efficiently convert diffuse sunlight. Semprius will use its expertise in cost-effective micro-transfer printing to fabricate and assemble the six-junction microcells. In addition to the cost benefits of micro-transfer printing, the team will utilize less expensive optics to reduce the cost of the system. By integrating cells that capture diffuse sunlight, Semprius’ innovation could expand the use of high-efficiency CPV in regions with low direct sunlight.