材料科学
热电效应
微观结构
晶界
纳米复合材料
纳米晶材料
复合数
热稳定性
复合材料
热导率
纳米晶
晶粒生长
化学工程
硫化铅
等温过程
声子
纳米颗粒
胶体
热电材料
纳米技术
微尺度化学
量子点
粒度
热的
光电子学
半导体
水溶液
纳米尺度
结构稳定性
打滑(空气动力学)
作者
Lixiang Xu,Lulu Huang,Weite Meng,Chenxin Wang,Shaoqing Lu,Shanhong Wan,Mengyao Li,Xuan Yang,Qingyue Wang,Wen‐Jun Wang,Andreu Cabot,Yu Zhang,Yu Liu,Khak Ho Lim
标识
DOI:10.1002/adfm.202528614
摘要
ABSTRACT Lead sulfide (PbS) is an earth‐abundant thermoelectric (TE) material. Cu, despite being an effective dopant, becomes thermally mobile at elevated temperatures, causing interfacial reactions and compositional inhomogeneity that undermine structural and electronic stability. In this study, we report a composite route that integrates colloidal PbS nanocrystals (NCs) with aqueous‐synthesized Cu‐doped PbS NCs to form PbS‐based nanocomposites. The approach integrates high Cu‐doping efficiency in aqueous synthesized NCs and structural robustness of colloidal NCs, thereby suppressing Cu migration at elevated temperature and improving thermal stability and mechanical robustness. The microstructure yields dense grain boundaries and heterointerfaces, where traces amount of Cu 2 S nanodomains are present, thereby modulating carrier concentration while enhancing phonon scattering. The nanocomposites exhibit 37% increase in mechanical strength, superior thermal stability over consecutive heating‐cooling cycles and prolonged isothermal test, and reduced lattice thermal conductivity of 0.63 W m −1 K −1 , resulting in a peak zT of ∼1.1 at 790 K. Furthermore, a single‐leg TE device fabricated from the optimized composite achieves a conversion efficiency of 6.3% at ΔT = 449 K, exceeding that of most PbS‐based counterparts operating at similar temperatures. This study demonstrates a microstructure and defect‐engineering that balances efficiency with long‐term service reliability for PbS‐based TEs.
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