Solar Cells Info

SUNY-Buffalo News Release /19 April 2007
Source:
http://www.buffalo.edu/news/8574

BUFFALO, N.Y. — Novel, self-assembly techniques for fabricating inorganic nanomaterials that could pave the way for more efficient and powerful solar cells, chemical sensors and detectors currently are being developed by a University at Buffalo chemist.

David F. Watson, Ph.D., an assistant professor in the Department of Chemistry in the University at Buffalo’s College of Arts and Sciences, has been awarded a prestigious National Science Foundation CAREER Award to conduct the research.  According to the NSF, the CAREER program recognizes and supports the early career-development activities of teacher-scholars “who are most likely to become the academic leaders of the 21st century.”

The research component of the grant involves a new approach to photochemistry, chemical reactions involving light, while the educational component will introduce students in the Buffalo Public Schools from underrepresented groups, including Native Americans, to principles of materials chemistry and scientific research through hands-on science activities.  The grant, which provides $576,100 over five years, will allow Watson and colleagues to conduct research aimed at better controlling the electron transfer reactivity of self-assembled inorganic nanomaterials.

In particular, Watson’s group is studying and characterizing photo-induced surface electron transfer reactions occurring within self-assembled inorganic nanomaterials, the reactions that drive solar cells and photocatalysts. The scientists will continue work on a self-assembly technique Watson developed for attaching quantum dots, tiny light-absorbing particles, to metal oxide films.  Using time-resolved spectroscopy, the researchers are able to probe systematically how composition, morphology and physical properties of the materials affect the kinetics and efficiency of electron transfer processes.

The researchers also will study how to improve the targeted patterning of nanoparticles onto metal oxide surfaces.  “This photochemical patterning strategy addresses one of the significant challenges in nanofabrication, to control both short-range and long-range order in nanostructured materials,” said Watson.  Short-range order refers to the organization of molecules and materials on the nanometer scale, while long-range order involves pattern formation on larger, even macroscopic, dimensions.  Watson’s approach combines the “top-down” and “bottom-up” methods of fabricating nanomaterials into a hybrid technique, in which photochemical reactions are used to organize nanoparticles on surfaces.

Substrates with high surface areas, he explained, allow for optically dense patterns and more efficient light harvesting, thereby potentially increasing the efficiency of solar cells and other devices.  “Because our surface substrate is the photochemically active component, our approach also might enable more widely applicable patterning techiques,” he said.

Watson’s grant also will provide summer research internships to students at various high schools in Buffalo through collaborations with faculty in the departments of chemistry and physics in the UB College of Arts and Sciences and in the departments of chemical and biological engineering and electrical engineering in the UB School of Engineering and Applied Sciences.

The educational program builds on the extensive partnership that exists between UB’s Department of Chemistry and Buffalo Public School 19, a Native American magnet school for middle school students.

Also with the support of the CAREER award, Watson is designing a “writing-intensive” course for advanced undergraduates and graduate students in the Department of Chemistry that will address one of his key educational concerns.

“Chemistry majors typically don’t do a lot of writing during their undergraduate or graduate careers, but it’s a huge part of what we do as scientists,” he said. “The idea is to get the students used to doing a lot of writing and to write mock reviews and critique each others’ work.”

Watson lives in Williamsville.  The University at Buffalo is a premier research-intensive public university, the largest and most comprehensive campus in the State University of New York.

Tom Simonite, NewScientist.com news service /  20 April 2007
Source:
http://environment.newscientist.com/article/dn11676

Heating plastic solar cells can alter their structure in a way that boosts efficiency, new research shows. The US and Korean scientists behind the discovery say it could ultimately allow flexible, lightweight plastic cells to replace rigid traditional cells.  Solar cells are usually made from silicon, which is inflexible and relatively heavy. By contrast, plastic solar cells could be more easily supported and wrapped around surfaces (see Pliable solar cells are on a roll). It might even be possible to spray light-collecting plastic onto a surface.
(more…)

By engineering nano-size branches and trunks into plastic solar cells, researchers have improved their ability to harvest the energy in sunlight

By David Biello, April 21, 2007
Source: Scientific American.com
http://www.sciam.com/article.cfm?chanID=sa002&articleID=1496CAD6-E7F2-99DF-34B95C45D49BA57C

Solar cells made from cheap, plastic polymer barely capture the energy in sunlight. Photons reflect off the plastic and it is too thin to absorb much, giving the polymers color. “The very fact that it has color is telling you this thing is not working as well as it should,” says David Carroll, a physicist at Wake Forest University in Winston-Salem, N.C. But plastic solar cells offer flexibility, are lightweight and, theoretically, low cost, which means they could be incorporated into a range of products. “You can’t think of doing anything cheaper than making Saran wrap and that’s basically what these are,” says Lawrence Kazmerski, director of the Department of Energy’s (DOE) National Center for Photovoltaics in Golden, Colo.
(more…)

By David Talbot, MIT Technology Review
http://www.technologyreview.com/read_article.aspx?ch=specialsections&sc=emerging&id=18285
Arthur Nozik hopes quantum dots will enable the production of more efficient and less expensive solar cells, finally making solar power competitive with other sources of electricty.
No renewable power source has as much theoretical potential as solar energy. But the promise of cheap and abundant solar power remains unmet, largely because today’s solar cells are so costly to make.  Photovoltaic cells use semiconductors to convert light energy into electrical current. The workhorse photo­voltaic material, silicon, performs this conversion fairly efficiently, but silicon cells are relatively expensive to manufacture. Some other semiconductors, which can be deposited as thin films, have reached market, but although they’re cheaper, their efficiency doesn’t compare to that of silicon. A new solution may be in the offing: some chemists think that quantum dots–tiny crystals of semi­conductors just a few nanometers wide–could at last make solar power cost-competitive with electricity from fossil fuels.
(more…)

By: University of New South Wales, May 3, 2007
source:
http://www.yubanet.com/artman/publish/article_56150.shtml

Solar energy could become more affordable following a breakthrough by UNSW scientists, who have boosted the efficiency of solar cell technology.  The advance could see the price of an installed solar system for an average house fall from around $20,000 to $15,000. Up to 45 percent of the cost of solar cell technology is due to the high cost of the silicon used to convert sunlight to electricity.
(more…)

Source:  BBC News /April 29, 2007
http://news.bbc.co.uk/2/hi/science/nature/6600213.stm

More than 100,000 people in rural India have benefited from an innovative loan scheme that helps families buy home solar power systems, the UN has said. The $1.5m project, led by the UN Environment Programme (Unep), supports Indian bankers who offer finance to people who want to purchase a unit.
(more…)

By Tung Shing Yi, Channel NewsAsia, 27 April 2007
Source: Chanel NewsAsia
http://www.channelnewsasia.com/stories/singaporebusinessnews/view/272911/1/.html

SINGAPORE : German-based energy firm SolarWorld is considering investing S$300 million in two solar plants in Singapore, over the next two years. SolarWorld is the world’s third largest solar energy company, and it received the International Headquarters award from the Economic Development Board (EDB) on Friday.
(more…)

PHOENIX, Apr 20, 2007
Source: FirstSolar press release
http://investor.firstsolar.com/releasedetail.cfm?ReleaseID=238798

First Solar, Inc. (Nasdaq:FSLR) announced that the Company had a ground breaking ceremony today on a new four-line solar module manufacturing plant in Kedah, Malaysia. Announced in Jan. 2007, the new plant will have an expected minimum annual nameplate capacity of 100MW.  The manufacturing plant will be located in Kulim Hi Tech Park located in Kedah, Malaysia and when fully ramped will employ approximately 500 people. Today’s groundbreaking puts First Solar on track to complete plant construction by late 2007, with full volume production expected by the end of 2008.
(more…)

Muscle and Speed: The Californian Solar Energy Market
Rotterdam, 26 April 2007
source:
http://www.solarplaza.com/content/pagina/SolarPlazaCalifornia/44978

With the creative energy of Silicon Valley, Mr. Arnold Schwarzenegger as governor and more than 3.2 billion dollars to spend, the solar industry in California and Silicon Valley is ready for a renewable energy boost. The flexibility of the Silicon Valley mindset – creating new and better products every day – the muscle power of Arnold Schwarzenegger, the abundant venture capital and the renewable fuel of government support could result in a booming solar industry!
(more…)

April 30, 2007, Singapore
Source: The China Post
http://www.chinapost.com.tw/news/archives/business/2007430/108439.htm

SolarWorld, the third largest solar energy company, is eager to tap into the rapidly growing Asia-Pacific energy market, founder and chief executive Frank Asbeck said in a published report on Saturday.  The German-based firm is planning to invest S$300 million (US$197 million) in two solar module and cell production plants in Singapore or South Korea within two years.
(more…)