Newby Samantha, Mirihanage Wajira, Fernando Anura
Department of Materials, Faculty of Science and Engineering, University of Manchester, Engineering Building A, Manchester M13 9PL, U.K.
ACS Omega. 2023 Mar 30;8(14):12613-12629. doi: 10.1021/acsomega.3c01176. eCollection 2023 Apr 11.
Smart textiles are transforming the future of wearable technology, and due to that, there has been a great deal of new research looking for alternative energy storage. Supercapacitors offer high discharge rates, flexibility, and long life cycles and can be integrated fully into a textile. Optimization of these new systems includes utilizing electrically conductive materials, employing successful electrostatic charge and/or faradaic responses, and fabricating a textile-based energy storage system without disrupting comfort, washability, and life cycle. This paper examines recent developments in fabrication methods and materials used to create textile supercapacitors and what challenges still remain.
智能纺织品正在改变可穿戴技术的未来,正因如此,出现了大量寻求替代储能方式的新研究。超级电容器具有高放电率、灵活性和长寿命周期,并且可以完全集成到纺织品中。这些新系统的优化包括利用导电材料、采用成功的静电荷和/或法拉第反应,以及制造基于纺织品的储能系统,同时不影响舒适度、可洗涤性和生命周期。本文探讨了用于制造纺织品超级电容器的制造方法和材料的最新进展以及仍然存在的挑战。
