Choi Myungwoo, Novak Travis G, Byen Jicheol, Lee Hyejeong, Baek Jinwook, Hong Seouggu, Kim Kisun, Song Jaeyong, Shin Hosun, Jeon Seokwoo
Department of Materials Science and Engineering, KAIST Institute for the Nanocentury (KINC), Korea Advanced Institute of Science and Technology (KAIST), Daejeon 34141, Republic of Korea.
Department of Nano Science, University of Science and Technology (UST), Interdisciplinary Materials Measurement Institute, Korea Research Institute of Standards and Science (KRISS), Daejeon 34113, Republic of Korea.
ACS Appl Mater Interfaces. 2021 May 26;13(20):24304-24313. doi: 10.1021/acsami.1c04828. Epub 2021 May 13.
Over the years, numerous studies have attempted to develop two-dimensional (2D) materials for improving both the applicability and performance of thermoelectric devices. Among the 2D materials, graphene is one of the promising candidates for thermoelectric materials owing to its extraordinary electrical properties, flexibility, and nontoxicity. However, graphene synthesized through traditional methods suffers from a low Seebeck coefficient and high thermal conductivity, resulting in an extremely low thermoelectric figure of merit (ZT). Here, we present an atomic-scale defect engineering strategy to improve the thermoelectric properties of graphene using embedded high-angle tilt boundary (HATB) domains in graphene films. These HATB domains serve as both energy filtering sites to filter out lower-energy charge carriers and scattering sites for phonons. Compared to the conventionally grown chemical vapor deposited graphene, the graphene with HATB domains shows an improved Seebeck coefficient (50.1 vs 21.1 μV K) and reduced thermal conductivity (382 vs 952 W mK), resulting in a ZT value that is ∼7 times greater at 350 K. This defect engineering strategy is promising not only for graphene-based materials but also for 2D materials, in general, where further research and optimization could overcome the limitations of conventional bulk thermoelectric materials in energy-harvesting systems.
多年来,众多研究试图开发二维(2D)材料,以提高热电设备的适用性和性能。在二维材料中,石墨烯因其非凡的电学性能、柔韧性和无毒特性,成为热电材料的有望候选者之一。然而,通过传统方法合成的石墨烯存在塞贝克系数低和热导率高的问题,导致其热电优值(ZT)极低。在此,我们提出一种原子尺度的缺陷工程策略,利用石墨烯薄膜中嵌入的高角度倾斜边界(HATB)域来改善石墨烯的热电性能。这些HATB域既作为能量过滤位点,滤除低能量电荷载流子,又作为声子的散射位点。与传统生长的化学气相沉积石墨烯相比,具有HATB域的石墨烯表现出更高的塞贝克系数(50.1对21.1 μV K)和更低的热导率(382对952 W mK),在350 K时ZT值增大了约7倍。这种缺陷工程策略不仅对基于石墨烯的材料有前景,总体而言对二维材料也有前景,进一步的研究和优化有望克服传统块体热电材料在能量收集系统中的局限性。
