Litcius/Paper detail

Ion–Electron Coupling Enables Ionic Thermoelectric Material with New Operation Mode and High Energy Density

Yongjie He, Shaowei Li, Rui Chen, Xu Liu, George Omololu Odunmbaku, Wei Fang, Xiaoxue Lin, Zeping Ou, Qianzhi Gou, Jiacheng Wang, Nabonswendé Aïda Nadège Ouedraogo, Jing Li, Meng Li, Chen Li, Yujie Zheng, Shanshan Chen, Yongli Zhou, Kuan Sun

2023Nano-Micro Letters54 citationsDOIOpen Access PDF

Abstract

Abstract Ionic thermoelectrics (i-TE) possesses great potential in powering distributed electronics because it can generate thermopower up to tens of millivolts per Kelvin. However, as ions cannot enter external circuit, the utilization of i-TE is currently based on capacitive charge/discharge, which results in discontinuous working mode and low energy density. Here, we introduce an ion–electron thermoelectric synergistic (IETS) effect by utilizing an ion–electron conductor. Electrons/holes can drift under the electric field generated by thermodiffusion of ions, thus converting the ionic current into electrical current that can pass through the external circuit. Due to the IETS effect, i-TE is able to operate continuously for over 3000 min. Moreover, our i-TE exhibits a thermopower of 32.7 mV K −1 and an energy density of 553.9 J m −2 , which is more than 6.9 times of the highest reported value. Consequently, direct powering of electronics is achieved with i-TE. This work provides a novel strategy for the design of high-performance i-TE materials.

Topics & Concepts

Ionic bondingThermoelectric effectIonMaterials scienceElectronCapacitive couplingCurrent densityConductorThermoelectric materialsSeebeck coefficientElectronicsOptoelectronicsVoltageElectrical engineeringChemistryPhysicsThermodynamicsComposite materialOrganic chemistryQuantum mechanicsEngineeringAdvanced Thermoelectric Materials and DevicesAdvanced battery technologies researchAdvanced Battery Materials and Technologies