Solar scientists rough up silicon panels to boost light capture

July 26, 2017
Figure 1. Fabrication of ultralow reflectance polycrystalline silicon wafers by use of the developed technology. Credit: Osaka University

Power generation cost using solar panels depends on getting as much electricity out of the panels as possible while keeping the manufacturing costs low. Anyone who has considered installing solar panels might be aware of the trade-off between efficiency and the initial cost of the panels. Engineers and researchers are finding new ways to obtain power out of solar modules, but doing so without adding to their costs is becoming more and more difficult.

Now a team of scientists at Osaka University has taken a step closer to making inexpensive solar that can deliver the same as more complex and expensive cells.

"Unmodified throw away light energy in the form of reflection, so most solar cells have some kind of antireflective coating," explains first author Daichi Irishika. "To avoid using these extra coatings we fabricated a submicron structure using a simple wet treatment directly into the silicon surfaces to give the cell its own antireflective coating."

Antireflective coatings, similar to those used on reading glasses, can help to get more light into solar cells and boost their electricity output. However, these coatings are expensive to produce, especially for covering large areas.

The Osaka team has previously made low reflection silicon cells using a much cheaper process based on the surface structure chemical transfer (SSCT) method to fabricate so-called black silicon. Chemically treating the front side of silicon cells produces tiny submicron silicon structures, which prevent light reflection and give a black appearance. The team has also developed a method to passivate the submicron silicon structures with huge surface area to prevent the recombination loss by deposition of phosphosilicate glass followed by heat treatment. This method can simultaneously form pn-junction to separate photo-generated electrons and holes, and therefore, it isn't an additional process.

Figure 2. Comparison of low reflectance mechanisms for previous technology and developed technology. Credit: Osaka University

Building on their previous success, the Osaka team turned their attention to the back side of the and created rougher light-trapping microstructures to capture even more infrared light.

Group leader Hikaru Kobayashi says, "Making very high efficiency is important but we should also consider the economics and practicality of any processes used to increase efficiency. The wet processes we have developed are simple yet effective, and our work with black silicon has real-world applications in making cost-effective silicon ."

More information: Daichi Irishika et al. Improvement of Conversion Efficiency of Silicon Solar Cells by Submicron-Textured Rear Reflector Obtained by Metal-Assisted Chemical Etching, Solar RRL (2017). DOI: 10.1002/solr.201700061

Provided by: Osaka University

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