Enhanced thermoelectric performance and mechanical strength in <scp>GeTe</scp> enable power generation and cooling
Jianglong Zhu, Fujie Zhang, Yilin Tai, Xiaobo Tan, Qian Deng, Pengfei Nan, Ruihuan Cheng, Chengliang Xia, Yue Chen, Binghui Ge, Ran Ang
Abstract
Abstract Finding a real thermoelectric (TE) material that excels in various aspects of TE performance, mechanical properties, TE power generation, and cooling is challenging for its commercialization. Herein, we report a novel multifunctional Ge 0.78 Cd 0.06 Pb 0.1 Sb 0.06 Te material with excellent TE performance and mechanical strength, which is utilized to construct candidate TE power generation and cooling devices near room temperature. Specifically, the effectiveness of band convergence, combined with optimized carrier concentration and electronic quality factor, distinctly boosts the Seebeck coefficient, thus greatly improving the power factor. Advanced electron microscopy observation indicates that complex multi‐scale hierarchical structures and strain field distributions lead to ultra‐low lattice thermal conductivity, and also effectively enhance mechanical properties. High ZT ~ 0.6 at 303 K, average ZT ave ~ 1.18 from 303 to 553 K, and Vickers hardness of ~200 H v in Ge 0.78 Cd 0.06 Pb 0.1 Sb 0.06 Te are obtained synchronously. Particularly, a 7‐pair TE cooling device with a maximum Δ T of ~45.9 K at T h = 328 K, and a conversion efficiency of ~5.2% at T h = 553 K is achieved in a single‐leg device. The present findings demonstrate a unique approach to developing superior multifunctional GeTe‐based alloys, opening up a promising avenue for commercial applications. image