The rapid development of wearable electronics has spurred demand for power sources that can be integrated with textiles and maintain stable output performance during dynamic movements. Traditional rigid power sources, due to their inflexibility and discomfort during physical activities, struggle to meet the requirements of wearable systems.

To address this challenge, researchers from the School of Materials & Energy, Southwest University, have developed a stretchable sweat-activated yarn battery (S-SAYB). It exhibits ultra-stable power output while offering excellent stretchability and deformability.

Innovative design, excellent performance
"The battery bridges the gap between stretchability and output stability, a significant long-standing challenge for stretchable power sources," explains senior author Prof. Zhisong Lu. Two key strategies were employed to achieve output stability during dynamic stretching: (1) Elastic fibers wrapped with a hydrophilic layer were designed to retain electrolytes for ion migration; (2) High electrode wrapping density was applied to minimize electrodes separation, which significantly increased the available ion migration pathways. “Our goal was to create a stretchable yarn battery with ultra-stable power output under varying strains,” adds Lu.

Large-scale production at a low cost
“The S-SAYBs can be scaled up to meter-scale fabrication using a self-designed wrapping machine and seamlessly integrated into electronic textiles through traditional techniques, such as weaving, knitting, sewing, and stitching,” explains Lu. In the study, S-SAYBs were integrated into headbands and sports T-shirts as reliable, flexible, stretchable, and strain-insensitive energy sources, providing stable power support for wearable electronic devices during exercise.

Biocompatibility with high safety
“Given that S-SAYBs are intended for use as skin contact devices, their biocompatibility to human skin could be a crucial factor,” says Lu. “The on-skin tests show that S-SAYBs can be integrated into textiles that come into contact with the skin as a safe energy source.”

Going forward, the research team may focus on the integration with diverse electronic devices, achieving multifunctional integration and promoting the upgrade of wearable devices from single function to intelligent systems.

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References

DOI

10.1016/j.wees.2025.06.002

Original Source URL

https://doi.org/10.1016/j.wees.2025.06.002

Funding information

This work was financially supported by the Chongqing Natural Science Foundation (Grant Nos. CSTB2022NSCQ-MSX0187 and CSTB2023NSCQ-MSX0818), the Sichuan Science and Technology Program (Grant No. 2024YFHZ0192), the Innovation Research 2035 Pilot Plan of Southwest University (Grant No. SWU-XDPY22014) and the Science and Technology Innovation Program of General Administration of Sport of China (Grant No. 23KJCX042).

Journal

Wearable Electronics