| Literature DB >> 29926528 |
Nan Wang1, Majid Kabiri Samani1, Hu Li2, Lan Dong3, Zhongwei Zhang3, Peng Su1, Shujing Chen4, Jie Chen3, Shirong Huang4, Guangjie Yuan4, Xiangfan Xu3, Baowen Li5, Klaus Leifer2, Lilei Ye6, Johan Liu1,4.
Abstract
Due to substantial phonon scattering induced by various structural defects, the in-plane thermal conductivity (K) of graphene films (GFs) is still inferior to the commercial pyrolytic graphite sheet (PGS). Here, the problem is solved by engineering the structures of GFs in the aspects of grain size, film alignment, and thickness, and interlayer binding energy. The maximum K of GFs reaches to 3200 W m-1 K-1 and outperforms PGS by 60%. The superior K of GFs is strongly related to its large and intact grains, which are over four times larger than the best PGS. The large smooth features about 11 µm and good layer alignment of GFs also benefit on reducing phonon scattering induced by wrinkles/defects. In addition, the presence of substantial turbostratic-stacking graphene is found up to 37% in thin GFs. The lacking of order in turbostratic-stacking graphene leads to very weak interlayer binding energy, which can significantly decrease the phonon interfacial scattering. The GFs also demonstrate excellent flexibility and high tensile strength, which is about three times higher than PGS. Therefore, GFs with optimized structures and properties show great potentials in thermal management of form-factor-driven electronics and other high-power-driven systems.Entities:
Keywords: grain size; graphene films; phonon transfer; thermal conductivity; turbostratic-stacking
Year: 2018 PMID: 29926528 DOI: 10.1002/smll.201801346
Source DB: PubMed Journal: Small ISSN: 1613-6810 Impact factor: 13.281