Abstract <p>Zn-based thermal charging devices, utilizing the synergistic effect of ion thermoextraction and thermodiffusion, are able to efficiently convert thermal energy into electrical energy and storage in the devices, making them a highly promising technology for low-grade heat recovery and utilization. However, the low output power density and energy conversion efficiency resulted by the slow diffusion kinetics of Zn<sup>2+</sup> hinder their development. Herein, we present a high-performance thermal charging cell design using Zn<sup>2+</sup>/NH<sub>4</sub><sup>+</sup> hybrid ion electrolyte, which not only maintains the high output voltage of the Zn-based thermoelectric system, but also significantly enhances the output power density due to the fast diffusion kinetics of NH<sub>4</sub><sup>+</sup>. Based on this strategy, the thermal charging cell displays a high thermopower of 12.5&#xa0;mV&#xa0;K<sup>−1</sup> and an excellent normalized power density of 19.6 mW m<sup>−2</sup>&#xa0;K<sup>−2</sup> at a temperature difference of 35&#xa0;K. The Carnot-relative efficiency is as high as 12.74%. Moreover, it can operate continuously for over 72&#xa0;h when the temperature difference persists, achieving a balance between thermoelectric conversion and output. This work provides a simple and effective strategy for the design of high-performance thermal charging cells for low-grade heat conversion and utilization.</p>

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A High-Performance Thermal Charging Cell with High Power Density and Long Runtime Enabled by Zn2+ and NH4+ Co-insertion

  • Zhiwei Han,
  • Shengliang Zhang,
  • Helang Huang,
  • Jing Wang,
  • Hui Dou,
  • Tianran Zhang,
  • Xiaogang Zhang

摘要

Abstract

Zn-based thermal charging devices, utilizing the synergistic effect of ion thermoextraction and thermodiffusion, are able to efficiently convert thermal energy into electrical energy and storage in the devices, making them a highly promising technology for low-grade heat recovery and utilization. However, the low output power density and energy conversion efficiency resulted by the slow diffusion kinetics of Zn2+ hinder their development. Herein, we present a high-performance thermal charging cell design using Zn2+/NH4+ hybrid ion electrolyte, which not only maintains the high output voltage of the Zn-based thermoelectric system, but also significantly enhances the output power density due to the fast diffusion kinetics of NH4+. Based on this strategy, the thermal charging cell displays a high thermopower of 12.5 mV K−1 and an excellent normalized power density of 19.6 mW m−2 K−2 at a temperature difference of 35 K. The Carnot-relative efficiency is as high as 12.74%. Moreover, it can operate continuously for over 72 h when the temperature difference persists, achieving a balance between thermoelectric conversion and output. This work provides a simple and effective strategy for the design of high-performance thermal charging cells for low-grade heat conversion and utilization.