The Nanosolar company blog has a post on their fast thin-film solar printing process.
As we are busy ramping our operation, we almost forgot to recognize achieving a major milestone in solar technology: The solar industry’s first 1GW production tool. Here it is:
Most production tools in the solar industry tend to have 10-30MW in annual production capacity. How is it possible to have a single tool with Gigawatt throughput?
This feat is fundamentally enabled through the proprietary nanoparticle ink we have invested so many years developing. It allows us to deliver efficient solar cells (presently up to more than 14%) that are simply printed.
Printing is a simple, fast, and robust coating process that in particular eliminates the need for expensive high-vacuum chambers and the kinds of high-vacuum based deposition techniques from industries where there’s a lot more $/sqm available for competitive manufacturing cost.
Our 1GW CIGS coater cost $1.65 million. At the 100 feet-per-minute speed shown in the video, that’s an astonishing two orders of magnitude more capital efficient than a high-vacuum process: a twenty times slower high-vacuum tool would have cost about ten times as much per tool.
Plus if we cared to run it even faster, we could. (The same coating technique works in principle for speeds up to 2000 feet-per-minute too. In fact, it turns out the faster we run, the better the coating!)
CNet reports that IBM is also getting into the thin-film solar market, in partnership with Japanese company Tokyo Ohka Kogyo (TOK).
The computing giant on Monday is expected to announce a deal with a Japanese semiconductor equipment manufacturer to make thin-film solar cells from CIGS, a combination of copper, indium, gallium, and selenide.
Neither IBM nor its partner, Tokyo Ohka Kogyo (TOK), plan to manufacture cells themselves. Rather, they will develop technology that can be licensed to solar companies in two or three years, said Supratik Guha, lead scientist for photovoltaics at IBM Research.
IBM has already built a prototype device. Once made at large volumes on a glass substrate, the cells are expected to deliver electricity at less than one dollar per watt at peak times--a long-held target of many solar outfits.
"We have the skills that we have developed in other areas--standard silicon semiconductors, materials chemistry--and we're looking to utilize those skills in the photovoltaic space and develop IP (intellectual property) and know-how that other people don't have," Guha said.
Traditional solar cells are made from silicon, but alternative thin-film materials are becoming a larger share of the market. Thin-film cells are less efficient at converting sunlight to electricity than silicon, but they require much less material to produce a cell, making them cost-competitive. Solar high-flier First Solar sells thin-film cells from cadmium telluride.
CIGS is a material that a number of companies are betting on, including Nanosolar, Global Solar Energy, Miasole, and Heliovolt. These companies are not producing cells at large volumes yet, but use of CIGS is expected to catch on quickly next year as their factories come online.
"CIGS will be the big story of 2009 because we know how many companies are putting in multimegawatts of CIGS (production capacity) in 2009," predicted solar expert Travis Bradford, president of the Prometheus Institute, who spoke at a recent Greentech Media solar briefing.
IBM's CIGS manufacturing technique came out of research IBM had done about 10 years ago in flexible electronics.
It's a break with the most common CIGS manufacturing process, called co-evaporation, in which active chemicals are immersed in a solution that gets removed in a vacuum.
IBM's "solution-based processing" calls for the chemicals to be dissolved in a liquid and then dried. It does not require a vacuum, doesn't require as much energy to run, and can be done faster than co-evaporation, Guha said.
IBM is also looking to leap-frog existing CIGS manufacturers on efficiency with a target of about 15 percent.
The efficiency of the CIGS cells on the market now is at about 9 percent or 10 percent. HelioVolt recently announced that it hit 12.2 percent efficiency with a process that is faster than co-evaporation. Global Solar said it expects to get to 14 percent, eventually.
The record for efficiency was done by the U.S. National Renewable Energy Research Laboratory (NREL) earlier this year, which reached 19.9 percent efficiency through a co-evaporation process.