Electronic thermal conductivity in suspended and supported bilayer graphene

Abstract

Electronic thermal conductivity κe is investigated, using Boltzmann transport equation approach, in a suspended and supported bilayer graphene (BLG) as a function of temperature and electron concentration. The electron scattering due to screened charged impurity, short-range disorder and acoustic phonon via deformation potential are considered for both suspended and supported BLG. Additionally, scattering due to surface polar phonons, is considered in supported BLG. In suspended BLG, calculated κe is compared with the experimental data leaving the phonon thermal conductivity. It is emphasized that κe is important in samples with very high electron concentration and reduced phonon thermal conductivity. κe is found to be about two times smaller in supported BLG compared to that in suspended BLG. With the reduced extrinsic disorders, in principle, the intrinsic scattering by acoustic phonons can set a fundamental limit on possible intrinsic κe.