Conductive Composite Fiber with Customizable Functionalities for Energy Harvesting and Electronic Textiles

A fiber-based triboelectric nanogenerator (FTENG) is an important technology for smart wearables, where conductive materials and triboelectric materials are two essential components for the F-TENG. However, the different physico-chemical properties between conductive metal materials and organic triboelectric materials often lead to interfacial failure problems, which is a great challenge for fabricating high-performance and stable F-TENGs. Herein, we designed a new conductive composite fiber (CCF) with customizable functionalities based on a core-spun yarn coating approach, which was applicable for a fiber-based TENG (CCF-TENG). By combing a core-spun method and a coating approach, triboelectric materials could be better incorporated on the surface of conductive fibers with the staple fibers to form a new composite structure with enhanced interfacial properties. The applicability of the method has been studied using different conductive and staple fibers and coating materials as well as different CCF diameters. As a demonstration, the open-circuit voltage and power density of the CCF-TENG reached 117 V and 213 mW/m(2), respectively. Moreover, a 2D fabric TENG was woven and used as a wearable sensor for motion detection. This work provided a new method for ID composite fibers with customizable functionalities for the applications in smart wearables.

Automated summary

A new method was proposed to design a conductive composite fiber (CCF) with customizable functionalities for fiber-based TENG, achieving enhanced interfacial properties. The CCF-TENG demonstrated high open-circuit voltage and power density, and could be woven into 2D fabric TENG for motion detection as a wearable sensor. This work provides a promising approach for developing customizable functional composite fibers for smart wearables.