3D Hierarchical Electrodes Boosting Ultrahigh Power Output for Gelatin-KCl-FeCN4-/3- Ionic Thermoelectric Cells

Ionic thermoelectric (i-TE) cells, using ions as energy carriers, have the advantage of achieving a high voltage of 1-5 V at approximately ambient temperature, showing a promise as a technology for powering Internet-of-Things (IoT) sensors. However, the low output power of i-TE cells restricts their applications. Here, a 3D hierarchical structure electrode is designed to enlarge the electroactive surface area, significantly increasing the thermogalvanic reaction sites and decreasing the interface charge transfer resistance. The quasi-solid-state gelatin-KCl-FeCN4-/3- i-TE cells achieve a record instantaneous output power density (8.9 mW m(-2) K-2) and an ultrahigh 2 h output energy density (E-2h) (80 J m(-2)) under an optimal temperature range. An average E-2h value of 59.4 J m(-2) is obtained over the course of a week of operation. A wearable device consisting of 24 i-TE cells can generate a high voltage of 2.8 V and an instantaneous output power of 68 mu W by harvesting body heat. A simple and easy-to-operate electrode optimization strategy is provided here to increase the long-term output power performance of i-TE cells. This work represents a promising approach to develop reliable and green power sources for IoT sensors near room temperature.