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May 2012 - We passed one million page views - thanks and Join already :-) September 2010 I am pleased to report that my essay titled A NEW METRIC WITH APPLICATIONS TO PHYSICS AND SOLVING CERTAIN HIGHER ORDERED DIFFERENTIAL EQUATIONS' has been published by Physics Essays published by the American Institute of Physics and appeared in their June 2010 quarterly. 40 years ago I took an honors degree in applied mathematics from the University of Waterloo. My interest was Relativity and my last year there saw me complete a 900 level course under Hanno Rund on his work in relativity,as well as differential geometry(pure math) and of course analysis. I continued researching new ideas and knowledge since that time and I have prepared a book for publication titled 'Paradigms Shift'. I maintain my blog as a day book and research tool to retain data and record impressions and interpretations on material read. Do take this moment to join my blog and receive Four items of interest daily Monday through Saturday. Since my topics are usually unique or at least obscure, the ads running through adsense are often interesting and worth dipping into while also supporting this blog in a small way.

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Saturday, June 26, 2010

NanoCoax Solar Cells



I do not know if this will lead to higher efficiency, but it may well lead to much cheaper for cells operating in the usual range of 8 to 15 % efficiency level.  And I must say that getting much better has been a litany of press releases and no commercial delivery.
So eight percent and cheap and reliable solves a lot of present day problems.  At least they have addressed the present problem.
This is promising and could see application quickly.

Highly efficient 'nanocoax' solar cell inspired by coaxial cable
By Mick Webb
08:53 June 9, 2010
http://www.gizmag.com/nanocoax-solar-cell-conversion-efficiency/15364/


http://c0378172.cdn.cloudfiles.rackspacecloud.com/nanocoaxjpg.jpg


Traditionally, the goal of high power conversion efficiency in thin film solar cells has been compromised by opposing optical and electrical constraints – while a cell needs to be thick enough to absorb adequate amounts of light, it must also be thin enough for the extraction of current. Rising to this “thick and thin” challenge, researchers at Boston College have designed a nanoscale solar cell based on the age-old technology that created the coaxial cable, promising a higher conversion efficiency than any thin film solar cell yet seen.

Dubbed “nanocoax”, the cell features solar architecture that makes it thick enough to capture light while being sufficiently thin to promote a more effective elicitation of current. Using the coaxial concept initially conceived in the 1800’s, the Boston College research team devised a method of cell creation that does not require crystalline materials.

According to professor of physics Michael Naughton, "Many groups around the world are working on nanowire-type solar cells, most using crystalline semiconductors. This nanocoax cell architecture, on the other hand, does not require crystalline materials, and therefore offers promise for lower-cost solar power with ultra thin absorbers. With continued optimization, efficiencies beyond anything achieved in conventional planar architectures may be possible, while using smaller quantities of less costly material."

Representing a new possibility for low cost, high efficiency solar power, the amorphous silicon nanocoax cells provide in excess of 8% power conversion efficiency, the highest of any nanostructured thin film solar cell to date. Invented at Boston College in 2005 and patented last year, researchers also found the ultra-thin nature of the nanocoax cells to reduce the light-induced degradation problem known as the Staebler-Wronski effect, which has been a major issue for conventional solar cells of this type.

The findings are featured in the online edition of Physica Status Solidi

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