Matrix plainification leads to high thermoelectric performance in plastic Cu2Se/SnSe composites
Pan Ying, Qingyang Jian, Yaru Gong, Tong Song, Yuxuan Yang, Yang Geng, Junquan Huang, Rongxin Sun, Chen Chen, Tao Shen, Yanan Li, Wei Dou, Congmin Liang, Yuqi Liu, Deshang Xiang, Tao Feng, Xiaoyu Fei, Yongsheng Zhang, Kun Song, Yang Zhang, Haijun Wu, Guodong Tang
Abstract
Thermoelectric technology exhibits significant potential for power generation and electronic cooling. In this study, we report the achievement of exceptional thermoelectric performance and high plasticity in stable Cu2Se/SnSe composites. A novel matrix plainification strategy was employed to eliminate lattice vacancies within the Cu2Se matrix of the Cu2Se/SnSe composites, resulting in a marked improvement in carrier mobility and power factor. The presence of quasi-coherent interfaces induces phonon scattering, reducing lattice thermal conductivity without compromising carrier mobility. Consequently, a high figure of merit (ZT) of 3.3 was attained in the Cu2Se/5 wt.% Sn0.96Pb0.01Zn0.03Se composite. Additionally, the presence of high-density nanotwins imparts remarkable plasticity to the composite, yielding a compressive strain of 12%. The secondary phase contributes to the stability of the composite by hindering the extensive migration of Cu ions through bonding interactions. Our findings present a novel strategy for enhancing the thermoelectric performance of composite semiconductors, with potential applicability to other thermoelectric systems. The authors propose a matrix plainification strategy to eliminate lattice vacancies in the Cu2Se matrix of the Cu2Se/SnSe composites, resulting in obvious improvement in carrier mobility and power factor, obtaining a high figure of merit of 3.3.