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Si Solar Panel Energy Yield Increased

Photonics.com
Jul 2010
DELFT, Netherlands, July 19, 2010 — Researchers from Delft University of Technology (TU Delft) have shown how the energy yield of relatively cheap solar panels, made of amorphous silicon, can be considerably raised — from around 7 percent to 9 percent.


Thin film silicon solar cells on a building in Germany. (Image: Inventux Technologies)


Researcher Gijs van Elzakker focused on solar panels that are made from so-called amorphous silicon, as opposed to the more commonly used crystalline silicon. Amorphous silicon has the great advantage that the solar panels can be produced relatively cheaply using a very thin layer of silicon (thin film solar cells).

However, the disadvantage of using amorphous silicon is that the yield is relatively low. While crystalline silicon achieves a yield of around 18 percent, amorphous silicon, until recently, remained at around 7 percent. This is partly because the amorphous silicon panels suffer from the so-called Staebler-Wronski effect. This phenomenon, which has manifests itself in the first hours that the panels are exposed to sunlight. Because of this the yield falls by around a third, from around 10 percent to around 7 percent.

In his doctoral research, van Elzakker investigated adaptations in the production process that could raise the yield. The silicon layer in the solar panels he studied is made of silane gas (SiH4). The structure of the silicon layer can be changed by diluting this silane gas with hydrogen during the production process. The use of hydrogen appears to enable the reduction of the negative Staebler-Wronski effect.

Van Elzakker concentrated, among other factors, on the proportion of hydrogen to silane gas. He determined the optimum ratio of hydrogen to silane in the production process.

“We showed that the influence of the Staebler-Wronski effect can be considerably reduced in this way. If this knowledge is applied in the manufacture of this type of solar cells, a yield of 9 per cent can be expected,” said van Elzakker.

His findings are already being applied on the production line of the German company Inventux Technologies, where he now works.

For more information, visit:  www.tudelft.nl 




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