Organic electronics are on the rise as a complement and, in some cases, a replacement to traditional silicon-based electronics. Thanks to simple manufacturing, high flexibility, and low weight combined with the electrical properties typically associated with traditional semiconductors, it can be useful for applications such as digital displays, energy storage, solar cells, sensors, and soft implants.

Conductive ink based on water. Photo credit Thor Balkhed Organic electronics are built from semiconducting plastics, known as conjugated polymers. However, processing conjugated polymers often requires environmentally hazardous, toxic, and flammable solvents. This is a major obstacle to the wide commercial and sustainable use of organic electronics.

Highly conductive

Now, researchers at Linköping University have developed a new sustainable method for processing these polymers from water. In addition to being more sustainable, the new inks are also highly conductive.Simone Fabiano, senior associate professor at the Laboratory of Organic Electronics. Photo credit Thor Balkhed

“Our research introduces a new approach to processing conjugated polymers using benign solvents such as water. With this method, called ground-state electron transfer, we not only get around the problem of using hazardous chemicals, but we can also demonstrate improvements in material properties and device performance,” says Simone Fabiano, senior associate professor at the Laboratory of Organic Electronics.

Sustainable electronics

When researchers tested the new conductive ink as a transport layer in organic solar cells, they found that both stability and efficiency were higher than with traditional materials. They also tested the ink to create electrochemical transistors and artificial neurons, demonstrating operating frequencies similar to biological neurons.

Johanna Heimonen, PhD student and Tiefeng Liu, postdoc both at Laboratory of Organic Electronics, are the main authors behind the article published in the journal Nature Communications. Photo credit Thor Balkhed “I believe that these results can have a transformative impact on the field of organic electronics. By enabling the processing of organic semiconductors from green and sustainable solvents like water, we can mass-produce electronic devices with minimal impact on the environment,” says Simone Fabiano, a Wallenberg Academy Fellow.

The research was funded by the Knut and Alice Wallenberg Foundation, the Wallenberg Initiative Materials Science for Sustainability (WISE), the Wallenberg Wood Science Centre (WWSC), the Swedish Research Council, Vinnova, the European Commission, and the Swedish government’s strategic investment in new functional materials (AFM) at Linköping University.

Article: Ground-state electron transfer in all-polymer donor:acceptor blends enables aqueous processing of water-insoluble conjugated polymers; Tiefeng Liu, Johanna Heimonen, Qilun Zhang, Chi-Yuan Yang, Jun-Da Huang, Han-Yan Wu, Marc-Antoine Stoeckel, Tom van der Pol, Yuxuan Li, Sang Young Jeong, Adam Marks, Xin-Yi Wang, Yuttapoom Puttisong, Asaminew Y. Shimolo, Xianjie Liu, Silan Zhang, Qifan Li, Matteo Massetti, Weimin M. Chen, Han Young Woo, Jian Pei, Iain McCulloch, Feng Gao, Mats Fahlman, Renee Kroon, Simone Fabiano; Nature Communications 2023, published online 20 December 2023: DOI: 10.1038/s41467-023-44153-7

When researchers tested the new conductive ink as a transport layer in organic solar cells, they found that both stability and efficiency were higher than with traditional materials. Photo credit Thor Balkhed