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Highly efficient fiber-shaped organic solar cells toward wearable flexible electronics

Engineering and Technology

Highly efficient fiber-shaped organic solar cells toward wearable flexible electronics

D. Lv, Q. Jiang, et al.

Discover the exciting advancements in fiber-shaped organic solar cells (FOSCs) that have surpassed 9% efficiency, thanks to the innovative work by Dan Lv, Qianqing Jiang, Yuanyuan Shang, and Dianyi Liu. These eco-friendly solar cells are tailor-made for wearable electronics, proving their capability by powering devices and even charging smartwatches woven into textiles.

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~3 min • Beginner • English
Abstract
Fiber-shaped organic solar cells (FOSCs) are promising power sources for wearable electronics due to their all-solid-state nature, ease of fabrication, environmental friendliness, and material stability. However, their efficiency has lagged behind other fiber-shaped solar cells. This work introduces non-fullerene acceptor (NFA)-based photoactive materials into FOSCs and employs low-cost industrial stainless-steel wire as the core electrode, with carbon nanotube yarn or silver wire as the counter electrode. Using a solution-processed PDINO electron transport layer and a PM6:Y6:PC71BM ternary active layer, FOSCs achieve up to 9.40% power conversion efficiency under AM 1.5 G. Systematic studies of transport layers, active layer, counter electrodes, solvents, and especially environmental humidity reveal key performance determinants. The devices can drive small electronics, be woven into textiles, and charge a smartwatch, highlighting strong potential for wearable applications.
Publisher
npj Flexible Electronics
Published On
Jun 07, 2022
Authors
Dan Lv, Qianqing Jiang, Yuanyuan Shang, Dianyi Liu
DOI
https://doi.org/https://doi.org/10.1038/s41528-022-00172-w
Tags
fiber-shaped solar cells
organic solar cells
non-fullerene acceptors
efficiency
wearable electronics
textiles
environmental friendliness

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