Park Woomin, Hwang Hyeonseok, Kim Sohee, Park Sungbin, Jang Kwang-Suk
Center for Bionano Intelligence Education and Research and Department of Applied Chemistry (Major in Bionano Convergence), Hanyang University, Ansan, Gyeonggi-do 15588, Republic of Korea.
ACS Appl Mater Interfaces. 2021 Feb 17;13(6):7208-7215. doi: 10.1021/acsami.0c20592. Epub 2021 Feb 2.
Herein, thermoelectric carbon nanoparticle (CNP)-carbon nanotube (CNT) heterostructures are introduced as a promising flexible thermoelectric material. The optimal barrier energy between the CNP and CNT increases the Seebeck coefficient () of the heterostructures through the energy filtering effect. For optimized thermoelectric performance, the CNP-CNT barrier energy can be effectively tuned by controlling the work function of the CNPs. The optimized p-type CNP-CNT heterostructures exhibited and power factor (PF) of 50.6 ± 1.4 μV K and 400 ± 26 μW m K, respectively. The n-type CNP-CNT heterostructures, optimized for another work function of the CNPs, exhibited and PF of up to -37.5 ± 3.4 μV K and 214 ± 42 μW m K, respectively. The energy harvesting capability of a thermoelectric generator prepared using p- and n-type CNP-CNT heterostructures with optimized barrier energies is demonstrated. The thermoelectric generator with 10 p-type and 9 n-type thermoelectric elements exhibited a maximum output power of 0.12 μW from a Δ of 5 K. This work shows a facile strategy for synthesizing thermoelectric CNP-CNT heterostructures with optimized energy filtering effects. Application to the thermoelectric device on a paper substrate is also discussed.
在此,引入了热电碳纳米颗粒(CNP)-碳纳米管(CNT)异质结构作为一种有前景的柔性热电材料。CNP和CNT之间的最佳势垒能量通过能量过滤效应提高了异质结构的塞贝克系数()。为了实现优化的热电性能,可以通过控制CNP的功函数来有效调节CNP-CNT势垒能量。优化后的p型CNP-CNT异质结构的塞贝克系数和功率因子(PF)分别为50.6±1.4μV K和400±26μW m K。针对CNP的另一种功函数进行优化的n型CNP-CNT异质结构的塞贝克系数和PF分别高达-37.5±3.4μV K和214±42μW m K。展示了使用具有优化势垒能量的p型和n型CNP-CNT异质结构制备的热电发电机的能量收集能力。具有10个p型和9个n型热电元件的热电发电机在5 K的温差下表现出0.12μW的最大输出功率。这项工作展示了一种合成具有优化能量过滤效应的热电CNP-CNT异质结构的简便策略。还讨论了其在纸质基板上的热电装置中的应用。
