Regulating zinc electroplating chemistry to achieve high energy coaxial fiber Zn ion supercapacitor for self-powered textile-based monitoring system

Coaxial fiber-shaped Zn-ion hybrid supercapacitors (CFZHSCs) with high power/energy density, long cycle life, splendid mechanical stability, and high safety are promising electrochemical energy storage devices for flexible and wearable electronics. However, the poor electrochemical performance of Zn anode severely restricts their practical application. To address this challenge, a highly reversible fiber-shaped Zn anode with controlled deposition morphology is developed based on theoretical calculation guided design of highly zincophilic 3D metal-organic-frameworks derived carbon with N- and OH-containing functional groups (N,O-MOFC) scaffold, by regulating electroplating chemistry of the initial nucleation and crystal growth time of zinc metal. Benefitting from fast ion diffusion ability of the hierarchically nanostructured 3D Zn/N,O-MOFC anode on the carbon nanotube fiber (CNTF), the assembled CFZHSCs device achieves a large volumetric specific capacitance of 128.06 F cm-3 and a high volumetric energy density of 57.63 mWh cm-3, surpassing the state-of-the-art FZHSCs device. More impressively, the efficient rechargeable capability of the fiber-shaped Zn anode also enables an adequately stable CFZHSCs device with the capacitance retention of 99.20% after 10,000 charge/discharge cycles and remarkable mechanical flexibility. As a conceptual demonstration of system integration, the asfabricated CFZHSCs device is integrated with triboelectric nanogenerator (TENG) yarn to achieve the selfpowered textile-based monitoring systems to stably detect temperature variation.

Automated summary

Coaxial fiber-shaped Zn-ion hybrid supercapacitors (CFZHSCs) are promising electrochemical energy storage devices for flexible and wearable electronics with high power/energy density, long cycle life, splendid mechanical stability, and high safety. The development of a highly reversible fiber-shaped Zn anode with controlled deposition morphology significantly improves the electrochemical performance of the devices. The CFZHSCs device exhibits a larger volumetric specific capacitance and a higher volumetric energy density compared to other devices, along with excellent capacitance retention and mechanical flexibility. In addition, the integration of the CFZHSCs device with a triboelectric nanogenerator enables a self-powered textile-based monitoring system for stable temperature detection.