Thermal conductivity and scattering models for graphene: From intrinsic scattering of pristine graphene to strong extrinsic scattering of functionalized graphene

“…The hardness is higher than the hardest diamond in nature, and it has excellent flexibility and can be bent at will. In ultrahigh thermal conductivity, because of its low-dimensional physics and unique honeycomb structure [5,6], graphene also has a very high thermal conductivity. The free-state single-layer graphene has a thermal conductivity of 5000 W•mK -1 at room temperature.…”

Structural Defects of Graphene Oxidation Reduction and Its High-Efficiency Structural Reforming Technology

“…The hardness is higher than the hardest diamond in nature, and it has excellent flexibility and can be bent at will. In ultrahigh thermal conductivity, because of its low-dimensional physics and unique honeycomb structure [5,6], graphene also has a very high thermal conductivity. The free-state single-layer graphene has a thermal conductivity of 5000 W•mK -1 at room temperature.…”

Structural Defects of Graphene Oxidation Reduction and Its High-Efficiency Structural Reforming Technology

Cooling rate dependence of Ni-catalyzed transformation of amorphous carbon into graphene in rapid thermal processing: An experimental and reactive molecular dynamics study

Effect of functionalization and defects on thermal conductivity of graphene sheets modified asphalt nanocomposites