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Glass microparticles enhance solar cells efficiency

November 20, 2017

Scientists from ITMO University suggested a new solar cell coating that combines features of an electrode and those of a light-trapping structure. The coating enabled researchers to cut down on reflected light and avoid solar cell overheating, thus increasing its overall efficiency by 20%. Moreover, the suggested method may be attractive for industrial applications due to its relatively low cost and simplicity.

The research was published in Optics Letters.

An entire range of materials can be used today for solar cell production. Solar cells based on amorphous silicon, for instance, are basically thin transparent films that may be applied to any surface including a window pane. When it comes to manufacturing solar cells, it is crucial to find ways to diminish light reflection from cells and avoid transparent electrode overheating, which prevents solar cells from working properly. Another key issue is to optimize the thickness of an active layer so that each photon reaching the solar cell is turned into electricity.

Now scientists from ITMO University devised a novel way to address these issues by putting inside the top electrode silica particles, later transferred into drop-like shape. The resulting structure functioned as an electrode as well as a light-trapping coat focusing the light on the solar cell. "To create such structures on the surface of a solar cell we use the method of atomic layer deposition of aluminia zinc oxide. We literally build these electrodes atom by atom," explains Mikhail Omelyanovich, lead author of the paper. "As a result, overall solar cell efficiency is improved by 20%. What is more, such an electrode can be used for thin solar cells composed of any material beyond amorphous silicon."

It took the team several years to develop an affordable solar cell manufacturing method that would appeal to the industry. "Three years ago we tried to cover cell surface with microspheres. Despite improving light absorption significantly, they had a major drawback in high reflectance rate. We considered removing the upper part of microspheres, so as to make something similar to a lens that would focus the light on the solar cell. However, while working over practical realization of this idea we found much better structure. On the whole, the final solution exceeded our expectations based on theoretical calculations," says Mikhail.

According to the authors, the manufacturing of solar cells with such surface coatings does not require complex technology and the process may be easily adapted for mass production.
-end-
Reference:

"Wide-angle light-trapping electrode for photovoltaic cells"
Mikhail Omelyanovich and Constantin Simovski
Optics Letters Sep. 19, 2017
https://www.osapublishing.org/ol/abstract.cfm?uri=ol-42-19-3726

ITMO University

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