Bloch-Gr\"uneisen temperature and universal scaling of normalized resistivity in doped graphene revisited

Abstract

In this work, we resolved some controversial issues on the Bloch-Gr\"uneisen (BG) temperature in doped graphene via analytical and numerical calculations based on full inelastic electron-acoustic-phonon (EAP) scattering rate and various approximation schemes. Analytic results for BG temperature obtained by semi-inelastic (SI) approximation (which gives scattering rates in excellent agreement with the full inelastic scattering rates) are compared with those obtained by quasi-elastic (QE) approximation and the commonly adopted value of LAF = 2 vLA kF/kB. It is found that the commonly adopted BG temperature in graphene (LAF) is about 5 times larger than the value obtained by the QE approximation and about 2.5 times larger than that by the SI approximation, when using the crossing-point temperature where low-temperature and high-temperature limits of the resistivity meet. The corrected analytic relation based on SI approximation agrees extremely well with the transition temperatures determined by fitting the the low- and high-T behavior of available experimental data of graphene's resistivity. We also introduce a way to determine the BG temperature including the full inelastic EAP scattering rate and the deviation of electron energy from the chemical potential (μ) numerically by finding the maximum of ∂ (μ,T)/∂ T. Using the analytic expression of BG,1 we can prove that the normalized resistivity defined as R1=(μ,T)/(μ,BG,1) plotted as a function of (T/BG,1) is independent of the carrier density. Applying our results to previous experimental data extracted shows a universal scaling behavior, which is different from previous studies.