The U.S. Department of Energy (DOE) announced up to $17.6 million for six early stage photovoltaic (PV) module incubator projects that focus on the initial manufacturing of advanced solar PV technologies.
Through these projects, companies will seek to accelerate the time
it takes to move innovative PV technologies from laboratory
demonstration into pilot production, and to reduce the cost, improve
performance and expand the manufacturing capacity of PV modules. These
awards will help fill the commercialization pipeline with advanced
solar technologies and bring a new generation of PV product suppliers
into the marketplace.
Including the cost share from industry, which will be at least 20%, the total research investment is expected to reach up to $35.4 million.
"These projects will help promote the development of a diverse set of photovoltaic technologies and ensure that the U.S. is a world leader in next-generation, cost-effective solar technologies," Acting Assistant Secretary for Energy Efficiency and Renewable Energy John Mizroch said. "These solar photovoltaic incubator awards will help accelerate the time it takes for innovative start-up companies to get their technologies to market."
Upon negotiation of their subcontracts through DOE’s National Renewable Energy Laboratory (NREL), the following six companies will begin their 18-month projects:
— 1366 Technologies (Lexington, Mass.) is developing a new cell architecture and related processes for low-cost multi-crystalline silicon cells. This project is expected to enhance cell performance by light-trapping texturing and grooves for self-aligned metallization fingers. By improving the light trapping and charge carrier movement within the cell, this project will significantly increase the efficiency of multicrystalline cells. By the end of the project, 1366 Technologies plans to deliver a 19 percent efficient, 15.6×15.6 cm2, multi-crystalline silicon cell with a technology that is applicable across the crystalline silicon cell industry. (Up to $3 million)
— Innovalight (Sunnyvale, Calif.) is developing very high-efficiency, low-cost solar cells and modules by ink-jet printing their proprietary "silicon ink" onto thin-crystalline silicon wafers. The company’s contact-less printing process has been demonstrated to significantly reduce both the manufacturing costs and the complexity required to make today’s highly-efficient cells and modules. (Up to $3 million)
— Skyline Solar (Mountain View, Calif.) has developed an integrated lightweight, single-axis tracked system that has been demonstrated to reflect and concentrate sunlight over 10X onto silicon cells. The use of mirrors to concentrate light will reduce the use of the greatest cost driver for traditional silicon modules, the solar cells, by over 90%. Additionally, the design leverages the mainstream PV industrial base and amplifies its capacity through significant concentration to enable rapid scaling. It seeks to dramatically lower the cost to manufacture modules and install complete systems to achieve a levelized cost of energy below grid parity. By the end of this project, Skyline plans to deliver modules that exceed 12m2 area and 15 percent aperture-area efficiency. (Up to $3 million)
— Solasta (Newton, Mass.) is using a novel cell design based on an amorphous-silicon "nanocoax" structure, which increases current and lowers materials cost by shortening the path charge carriers must travel to the cell’s conducting wires. This approach effectively decouples the optical and electronic pathways. If successful, Solasta will deliver 15 percent efficient, 100-cm2 pre-production cells at the end of the project. (Up to $2.6 million)
— Solexel (Milpitas, Calif.) plans to commercialize a disruptive, 3D, high efficiency mono-crystalline silicon cell technology, while dramatically reducing manufacturing cost per watt. Through a series of novel yet low cost processing steps, this project will manufacture a solar cell architecture which efficiently traps light using minimal material. At the end of this project, Solexel plans to deliver a 17-19 percent efficient, 156×156 mm2, single-crystal cell that consumes substantially lower silicon per watt than conventionally sliced wafers. Solexel aspires to be a gigawatt-scale PV producer within five years. (Up to $3 million)
— Spire Semiconductor (Hudson, N.H.) plans on opening up the design space for three-junction tandem solar cells by growing differentiated bi-facial cells on a Gallium Arsenide substrate. This approach will allow spire to better optimize the optical properties of their device layers to better match the solar spectrum. Spire Semiconductor is targeting cell efficiencies over 42% using a low-cost manufacturing method. (Up to $2.97 million)