Manipulating Thermal Conductivity via Targeted Phonon Excitation

Thermal conductivity is a critical property for materials in many practical applications, such as thermoelectric devices and heat dissipation. It has become an issue of great concern how thermal conductivity can be effectively manipulated. In this work, we manipulate the thermal conductivities of graphene and graphene nanoribbon via targeted phonon quantal excitation. Ab initio calculations show that the thermal conductivity of graphene can be tailored in the range of 45% to 155%, compared with the intrinsic value. Molecular dynamics simulations also exhibit a similar trend (82%-124%) for graphene nanoribbon. This strategy provides a new way for manipulating thermal conductivity in-situ without changing the composition of materials.