Flexible organic electronics can be used to create wearable devices but the synthesis of organic electronic materials typically involves hazardous solvents, creates toxic by-products and has various other environmental and economic costs.

Being able to recycle organic electronic materials and devices in an eco-friendly and economical manner is thus key for their application in sustainable wearable electronics. Here we report organic flexible electronic devices with closed-loop recycling of each component.

We develop approaches to recapture and reuse organic conductors, semiconductors and gate dielec-trics, and evaluate the reliability of the recycled materials. Our fabrication and recycling processes also use only eco-friendly solvents (water, anisole and acetone).

We illustrate the capabilities of the approach with various recyclable organic flexible electronic de-vices, including electrophysiological sensing electrodes, keypads, heaters/temperature sensors, electrochemical transistors and inverters. We also develop a sustainable device cycle by reconstructing various organic flexible electronics, which are fabricated using recycled materials from different functional devices without further replenishment.

A research team, led by Professor Kyoseung Sim in the Department of Chemistry at UNIST, has achieved a groundbreaking milestone in sustainable wearable devices. Their cutting-edge method enables closed-loop recycling of organic electronic materials, addressing environmental concerns and paving the way for a sustainable future in the electronic device industry.

The synthesis of organic electronic materials has historically been associated with hazardous solvents, toxic by-products, and significant environmental and economic costs. However, this groundbreaking research has unlocked the potential for recycling and repurposing organic conduc-tors, semiconductors, and gate dielectrics in an eco-friendly and economically viable manner.

The closed-loop recycling, introduced by the research team, incorporates eco-friendly solvents, such as water, anisole, and acetone, throughout the fabrication and recycling processes. By elimi-nating the reliance on harmful substances, this innovation represents a significant stride towards sustainable manufacturing and recycling practices for organic flexible electronic devices.

To demonstrate the capabilities of this approach, the team successfully created a range of recyclable organic flexible electronic devices, including electrophysiological sensing electrodes, keypads, heaters/temperature sensors, electrochemical transistors, and inverters. Moreover, they established a sustainable device cycle by reconstructing various organic flexible electronics using recycled ma-terials from different functional devices, without the need for additional resources.

Thorough evaluations of the recyclability of the organic electronic materials have yielded remarka-ble results. Organic conductors demonstrated the ability to be recycled more than five times, organ-ic insulating gels could be reused over 30 times, and organic semiconductors showed a recycling potential of approximately one cycle.

“This study offers the first solution to the environmental challenges posed by the use of organic electronic materials in the electronics industry,” stated Professor Sim. “The outcomes of this research are expected to be a pivotal milestone and a key technology that shapes the future of sustain-able electronic devices.”

The study, with Haechan Park as the first author, has been published in the online version of Nature Electronics on Dec. 16, 2023. The research received support from the National Research Foundation of Korea (NRF) and the Ministry of Science and ICT (MSIT), and UNIST.

Journal Reference
Haechan Park, Sehyun Kim, Juyeong Lee, et al., “Organic flexible electronics with closed-loop re-cycling for sustainable wearable technology,” Nat. Electron., (2023).