“It’s small, its elusive, but its very friendly!” says Tom Sepe of the Higgs-Boson particle he photographed in his garage on Monday.
Scientists have been looking for the Higgs-Boson or “God Particle” for decades but “They’ve been going about it all wrong!” says Sepe, who was able to coax the quantum particle out of hiding with just the right music.
As Sepe explains; “Sages have been saying for thousands of years that every thing is just vibration, the music of the spheres and whatnot. Look, the Higgs-Boson has been here since the dawn of time (or just .0000001 seconds after) it has good tastes, it’s seen it all. You can’t just build a big a huge ugly billion dollar machine and expect a cool party. These things have to be understood from an emotional point of view as well! Its quantum physics man! Its Craazzy! We understand this stuff out in California.”
Researchers may have found a better, cheaper alternative to Silicon for photovoltaic cells; Iron Pyrite or Fool’s Gold! It is being researched as a super absorber PV solar energy, and has the distinct advantage of being far more abundant and inexpensive, as detailed in the article release today, excerpted below:
By Robert Sanders, Media Relations| 17 February 2009
BERKELEY — Unconventional solar cell materials that are as abundant but much less costly than silicon and other semiconductors in use today could substantially reduce the cost of solar photovoltaics, according to a new study from the Energy and Resources Group and the Department of Chemistry at the University of California, Berkeley, and the Lawrence Berkeley National Laboratory (LBNL).
These materials, some of which are highly abundant, could expand the potential for solar cells to become a globally significant source of low-carbon energy, the study authors said.
Solar power collectors, like these photovoltaic panels on a New Mexico high school roof, could be installed much more widely if they could be manufactured from less-costly materials. (U.S. Department of Energy photo)
The analysis, which appeared online Feb. 13 in Environmental Science & Technology, examines the two most pressing challenges to large-scale deployment of solar photovoltaics as the world moves toward a carbon neutral future: cost per kilowatt hour and total resource abundance. The UC Berkeley study evaluated 23 promising semiconducting materials and discovered that 12 are abundant enough to meet or exceed annual worldwide energy demand. Of those 12, nine have a significant raw material cost reduction over traditional crystalline silicon, the most widely used photovoltaic material in mass production today.
The work provides a roadmap for research into novel solar cell types precisely when the U. S. Department of Energy and other funders plan to expand their efforts to link new basic research to deployment efforts as part of a national effort to greatly expand the use of clean energy, according to Daniel Kammen, UC Berkeley professor of energy and resources and director of the Renewable and Appropriate Energy Laboratory.