Electronic thermal conductivity and thermopower of armchair graphene nanoribbons Original Research Article

A theoretical investigation of the diffusion contribution to thermopower, Sd, and the electronic thermal conductivity, κe, of semiconducting armchair graphene nanoribbons (GNRs) is made for T ⩽ 300 K. Considering the electrons to be scattered by edge roughness, impurities and deformation-potential coupled acoustic phonons and optical phonons, expressions for Sd and κe are obtained. Numerical calculations of Sd and κe, as functions of temperature and linear carrier density, bring out the relative importance of the contributing scattering mechanisms. A GNR of width 5 nm, supporting an electron density 2 × 108 m−1, is found to exhibit room temperature values of Sd and κe as 42 μV/K and 26.5 W/mK, respectively. A decrease in armchair GNR width, is found to enhance Sd and reduce κe. The effect of varying the electron density is to increase their magnitude when Fermi energy moves into the second subband. An analysis of thermopower and thermal conductivity data in clean armchair GNR samples will enable better understanding of the electron–phonon interaction.