Semitransparent and Flexible - Solar Cells made from atomically thin sheet
Researchers at Tohoku University have developed an innovative method for fabricating semitransparent and flexible solar cells with atomically thin 2D materials. The new technology improves power conversion efficiency of up to 0.7% - this is the highest value for solar cells made from transparent 2D sheet materials.
Transparent or semi-transparent solar cells with excellent mechanical flexibility have attracted much attention as next-generation smart solar cells. They can be used in various applications such as on the surfaces of windows, front display panels of personal computers and cell phones, and human skin. But issues remain with regards to improving their power conversion efficiency, optical transparency, flexibility, stability and scalability.
Led by Associate Professor T. Kato, the team showed easy and scalable fabrication of semitransparent and flexible solar cell using transition metal dichalcogenides (TMDs) - an atomically thin 2D material. Using a Schottky-type configuration, power conversion efficiency can be increased up to 0.7%, which is the highest value reported with few-layered TMDs. Clear power generation was also observed for a device fabricated on a large transparent and flexible substrate.
“Since our device structure, Schottky-type solar cell, is very simple, the TMDs-based Schottky-type solar cell possesses good properties for scalability, which is one of the most important elements for use in practical applications.” says Kato.
“The transparent and semi-transparent solar cell can be used in a variety of ways. This new type of solar cell is likely to have impact on the technologies we use in daily life in the near future.”
Details of this study were published online on September 20 in Scientific Reports
Toshiki Akama, Wakana Okita, Reito Nagai, Chao Li, Toshiro Kaneko & Toshiaki Kato
Title: Schottky solar cell using few-layered transition metal dichalcogenides toward large-scale fabrication of semitransparent and flexible power generator
Journal: Scientific Reports
Division of Public Relations, School of Engineering