Nextnano is a company that focuses on the development of software for semiconductor nanodevices in the technology industry. The company's main product is a software that allows engineers and scientists to model, design, and understand the properties of nanoscale semiconductor structures and devices. The company primarily sells to the semiconductor and quantum science industries. It is based in Germany.

Gratings Incorporated is a company that received a STTR Phase I grant for a project entitled: High Efficiency Thin-film Photovoltaics on Low-cost Substrates by Layer Transfer. Their their award is funded under the American Recovery and Reinvestment Act of 2009 and their project will apply high aspect ratio, nm-scale, columnar, and crystalline Si structures as templates for high-quality growth of thin-film GaAs solar cells on low-cost flexible substrates. Sub-10-nm Si seed layers are expected to facilitate growth of low-defect density GaAs films. The aspect ratio of nm-scale structures also serve as sacrificial layers for removal of completed GaAs solar cell. Epitaxial growth and characterization of GaAs films on nm-scale Si structures will be carried out at the Center for High Technology at the University of New Mexico. Successful phase I STTR research will lead to commercialization of high (~ 20 %) efficient, flexible solar cells for applications in a wide range of terrestrial and space environments. Multiple substrate re-use and inherent large area processing capability of Si will result in significant cost reductions. High quality heteroepitaxial GaAs growth on Si has been a subject of intense research. Due to its direct bandgap, GaAs is attractive for a number of optoelectronics applications and its integration with Si-based microelectronics has been a cherished goal. The lattice and thermal expansion mismatches with Si make it difficult to grow good device quality layers. We have recently demonstrated as the Si seed dimension is reduced below 100 nm dimensions, the quality of heteroepitaxial growth increases rapidly. The nm-scale Si structures are formed using low-cost, large area methods based on conventional integrated circuit processing methods. Successful research effort will lead to reduction in PV generation costs, and enhanced applicability of thin-film PV in terrestrial and space environments because in contrast with competing thin-film solar cells, GaAs thin-film solar cells will not suffer from light-induced performance degradation.

AOS Solar was started in 2005 to combine the material cost and manufacturing process economics of thin film solar PV with the efficiency and reliability of crystalline silicon solar PV. The company have an initial prototype solar coupon built and tested using technology. nnThe company's key enablers to achieve market traction are the cost and reliability of the company's product. The silicon on glass (SOG) technology the company are developing will enable solar panels costing around $1/watt to manufacture on the company's pilot line, with lower costs as the company ramp up production due to manufacturing efficiencies and learning curve. Solar silicon is an established technology with proven 20+ year life (versus newer thin film technologies). nnToday the company have working coupons at 7.5% efficiency and the company are working to scale up to larger cells with target 9% efficiency in Q-1, 2008. The company's form factor and efficiency limits are based on first generation technology. By scaling the company's manufacturing and improving the company's technology the company expect to achieve 16 - 18% efficiency in a single junction and 22 - 24% efficiency in a double junction module. nnThe company's A round funding will be used to continue development of the company's equipment / process technology in order to manufacture on larger substrates (2.5' x 4' glass) and to design a scaled up manufacturing line (30+MW annual capacity) based on this development.

SpectraWatt manufactures and distributes silicon solar cells for use in solar modules. SpectraWatt aims to enable solar generated electricity to compete, on an unsubsidized basis, with conventional sources of electricity.

developed a technology that aims to allow for more efficient use of crystalline silicon in solar cells - a that could allow solar cells to generate electricity at costs competitive with conventional energy sources.

Accustrata is a company that received a SBIR Phase IB grant for a project entitled: Real time optical control system for thin film solar cell manufacturing. Their research project relates to a real-time optical control system in the manufacture of next generation thin film solar cells and panels. The proposed system improves thin film solar cell manufacturing by improving the quality of the individual solar cells and panels. It allows manufacturing of more consistent and uniform products resulting in higher solar conversion efficiency and manufacturing yield. The proposed system uses patented miniature fiber optic sensors, installed at many locations in the film deposition chambers. They monitor different spots on the substrate and obtain real time measurements of film properties. The system compares the measured with the targeted values and provides immediate correction, improving film uniformity and narrowing material property distribution. It returns most of the products to their targeted specification, which would otherwise be rejected. This proposal will reduce waste and improve the manufacturing yield and the conversion efficiency of thin film solar cells and panels. It has specific benefits for the large-size solar panels, which are manufactured at higher cost today due to insufficient manufacturing yield. The proposed technology will reduce the time it takes for solar panels to reach grid parity with traditional energy sources. The proposed technology will also facilitate the development of numerous other applications for next generation thin film based products such as photonic crystals, nanotechnology, meta-materials, multi-junction solar cells, printing and counterfeiting control. This award is funded under the American Recovery and Reinvestment Act of 2009 (Public Law 111-5).