Litcius/Paper detail

Electrically-driven robust tuning of lattice thermal conductivity

E Zhou, Donghai Wei, Jing Wu, Guangzhao Qin, Ming Hu

2022Physical Chemistry Chemical Physics14 citationsDOIOpen Access PDF

Abstract

, with bilayer graphene, monolayer silicene, and germanene as study cases. The monotonically decreasing trend of thermal conductivity in all three materials is revealed. A significant effect on the scattering rate is found to be responsible for the decreased thermal conductivity driven by the electric field. Further evidence shows that the reconstruction of internal electric field and generation of induced charges lead to increased scattering rate from strong phonon anharmonicity. Thus, the ultralow thermal conductivity emerges with the application of external electric fields. Applying an external electric field to regulate thermal conductivity illustrates a constructive idea for highly efficient thermal management.

Topics & Concepts

Electric fieldSiliceneCondensed matter physicsThermal conductivityMaterials sciencePhononScatteringScattering ratePhonon scatteringGermaneneThermalGrapheneNanotechnologyPhysicsOpticsThermodynamicsComposite materialSuperconductivityQuantum mechanicsThermal properties of materialsGraphene research and applicationsAdvanced Thermoelectric Materials and Devices