6/14/2010
In Angus Rockett’s lab, researchers are discovering that the secret to harnessing more solar power may be more “imperfect” materials.
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In Angus Rockett’s lab, researchers are discovering that the secret to harnessing more solar power may be more “imperfect” materials.
Rockett, a professor of materials science and engineering, has spent years studying the photovoltaics, or solar electricity, made of a material called Cu(In,Ga)Se2, otherwise known as CIGS. His team has concluded that materials with more “holes” appear to capture more energy than materials with fewer holes.
"It's a hard concept to get used to, but the idea is that in material with these holes, energy is collected in three dimensions rather than one," says Rockett, a researcher in the Coordinated Science Laboratory. "That leads to more efficient power generation."
In the solar cells, solar electricity is produced when sunlight is absorbed and the energy in the excited electrons is collected. As the electron works to return to the material in which it was excited, it transmits power from the sunlight to the circuit.
With that in mind, the team examined two kinds of material: a single crystal material and a polycrystal material with many individual crystal grains. Rockett's group showed that polycrystals -- which resemble Swiss cheese -- with gaps between the grains make the best solar cells. Materials without holes between the grains had a more difficult time collecting energy, while the single crystals with no grain boundaries fared even worse and made the least power.
The end result: The polycrystal material with the most holes produced the most power.