材料科学
碳纳米管
热电效应
兴奋剂
纳米技术
过滤(数学)
过程(计算)
碳纤维
化学工程
复合材料
光电子学
复合数
计算机科学
工程类
物理
操作系统
统计
热力学
数学
作者
Minsuk Park,Seongjoo Hwang,Takahiro Nakae,Hiroshi Sakaguchi,Sang‐Yong Ju
标识
DOI:10.1021/acsami.5c01667
摘要
The superiority of thermoelectric (TE) performance based on single-walled carbon nanotubes (SWCNTs) has conventionally involved the pursuit of a highly pure semiconducting (s)-SWCNT and subsequent doping. Herein, we report that a minute quantity of metallic (m)-SWCNT facilitates the doping of s-SWCNT, leading to the highest achieved power factor (PF) and figure of merit (zT) among SWCNT film-based TE devices without compromising the Seebeck coefficient (α). The controlled introduction of trace amounts of m-SWCNT in s-SWCNT films is achieved through repetitive filtration (RF) processes for film preparation. Spectroscopic analyses confirm the efficacy of the RF process in elevating s-SWCNT purity to over 99%, while diminishing levels of m-SWCNT, bundling size, and carbonaceous impurities. The doping states of s-SWCNT films, determined by optical bleaching, vary with the number of RF cycles, attributed to self-doping facilitated by endogenous m-SWCNTs possessing different Fermi levels and O2/H2O redox environments. TE devices derived from this approach demonstrate that, with an α of as high as 645 μV/K and higher doped states around the mid-RF cycle number, the s-SWCNT film achieves peak PF (8309 μW/m·K2) and zT (0.17). This self-doping strategy proves to be effective for positive doping, enhancing electrical conductivity, and improving TE performance without external dopants.
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