热电材料
可持续能源
材料科学
工程物理
能量收集
热电效应
能量(信号处理)
纳米技术
环境科学
可再生能源
电气工程
物理
复合材料
工程类
热导率
热力学
量子力学
作者
Wenyi Chen,Meng Li,Xiaodong Wang,Joseph Otte,Min Zhang,Chengyang Zhang,Tianyi Cao,Boxuan Hu,Nanhai Li,Wei‐Di Liu,Matthew S. Dargusch,Jin Zou,Qiang Sun,Zhi‐Gang Chen,Xiao‐Lei Shi
标识
DOI:10.1038/s41467-025-62336-2
摘要
Abstract The high cost and complexity of fabrication limit the large-scale application of flexible inorganic thermoelectric materials. Currently, Bi 2 Te 3 -based materials are the only commercially viable option, but the inclusion of Te significantly increases production costs. This study presents a simple and cost-effective method for fabricating flexible Ag 2 Se films, employing a combination of solvothermal synthesis, screen printing, and spark plasma sintering. The incorporation of a small amount of Te improves film density and facilitates Te diffusion doping, leading to Ag 2 Se films with a high power factor of 25.7 μW cm −1 K −2 and a figure of merit ( ZT ) of 1.06 at 303 K. These films exhibit excellent flexibility, retaining 96% of their performance after 1000 bending cycles at a 5 mm bending radius. Additionally, we design a flexible thermoelectric device featuring a triangular p-n junction structure based on these films. This device achieves a normalized power density of 4.8 μW cm −2 K −2 at a temperature difference of 20 K and a maximum cooling of 29.8 K with an input current of 92.4 mA. These findings highlight the potential of this fabrication method for developing thermoelectric materials and devices for energy harvesting and cooling applications.
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