Polymer solar cells could be even cheaper and more reliable thanks to a breakthrough by researchers at Linköping University and the Chinese Academy of Sciences (CAS). This work is about avoiding costly and unstable fullerenes.
In recent years, polymer solar cells have emerged as a low cost alternative to silicon solar cells. In order to obtain high efficiency, fullerenes are usually required in polymer solar cells to separate charge carriers. However, fullerenes are unstable under illumination, and form large crystals at high temperatures.
Now, a team of chemists led by Professor Jianhui Hou at the CAS has set a new world record for fullerene-free polymer solar cells by developing a unique combination of a polymer called PBDB-T and a small molecule called ITIC. With this combination, the sun’s energy is converted with an efficiency of 11%, a value that strikes most solar cells with fullerenes, and all without fullerenes.
Feng Gao, together with his colleagues Olle Inganäs and Deping Qian at Linköping University, have characterized the loss spectroscopy of photovoltage (Voc), a key figure for solar cells, and proposed approaches to further improving the device performance.
The two research groups are now presenting their results in the high-profile journal Advanced Materials.
“We have demonstrated that it is possible to achieve high efficiency without using fullerene, and that such solar cells are also highly stable to heat. Because solar cells are working under constant solar radiation, good thermal stability is very important,” says Feng Gao, a physicist at the Department of Physics, Chemistry and Biology, Linköping University.
“The combination of high efficiency and good thermal stability suggests that polymer solar cells, which can be easily manufactured using low-cost roll-to-roll printing technology, now come a step closer to commercialization,” says Feng Gao.
Article: Fullerene-free polymer solar cells with over 11% efficiency and excellent thermal stability, by Wenchao Zhao, Deping Qian, Shaoqing Zhang, Sunsun Li, Olle Inganäs, Feng Gao and Jianhui Hou. Advanced Materials 2016. DOI: 10.1002/adma.201600281
Source: Linköping University