Unusual Enhancement in Intrinsic Thermal Conductivity of Multilayer Graphene by Tensile Strains

Youdi Kuang, Lucas Lindsay, Baoling Huang

Research output: Contribution to journalArticlepeer-review

99 Scopus citations

Abstract

Using the Boltzmann-Peierls equation for phonon transport approach with the inputs of interatomic force constants from the self-consistent charge density functional tight binding method, we calculate the room-temperature in-plane lattice thermal conductivities k of multilayer graphene (up to four layers) and graphite under different isotropic tensile strains. The calculated in-plane k of graphite, finite monolayer graphene and 3-layer graphene agree well with previous experiments. For unstrained graphene systems, both the intrinsic k and the extent of the diffusive transport regime present a drastic dimensional transition in going from monolayer to 2-layer graphene and thereafter a gradual transition to the graphite limit. We find a peak enhancement of intrinsic k for multilayer graphene and graphite with increasing strain with the largest enhancement amplitude ∼40%. Competition between the decreased mode heat capacities and the increased lifetimes of flexural phonons with increasing strain contribute to this k behavior. Similar k behavior is observed for 2-layer hexagonal boron nitride systems. This study provides insights into engineering k of multilayer graphene and boron nitride by strain and into the nature of thermal transport in quasi-two-dimensional and highly anisotropic systems.

Original languageEnglish
Pages (from-to)6121-6127
Number of pages7
JournalNano Letters
Volume15
Issue number9
DOIs
StatePublished - Sep 9 2015

Funding

FundersFunder number
Oak Ridge National Laboratory
Office of Science
U.S. Department of Energy

    Keywords

    • Tensile strain
    • density functional tight binding
    • multilayer graphene
    • phonon thermal transport
    • thermal conductivity

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