Kohn anomalies and non-adiabaticity in doped carbon nanotubes
Abstract
The high-frequency Raman-active phonon modes of metallic single-walled carbon nanotubes (SWNTs) are thought to be characterized by Kohn anomalies (KAs), which are expected to be modified by the doping-induced tuning of the Fermi energy level εF, obtained through the intercalation of SWNTs with alkali atoms or by the application of a gate potential. We present a Density-Functional Theory (DFT) study of the phonon properties of a (9,9) metallic SWNT as a function of electronic doping. For such study, we use, as in standard DFT calculations of vibrational properties, the Born-Oppenheimer (BO) approximation. We also develop an analytical model capable of reproducing and interpreting our DFT results. Both DFT calculations and this model predict, for increasing doping levels, a series of EPC-induced KAs in the vibrational mode parallel to the tube axis at the point of the Brillouin zone, usually indicated in Raman spectroscopy as the G- peak. Such KAs would arise each time a new conduction band is populated. However, we show that they are an artifact of the BO approximation. The inclusion of non-adiabatic (NA) effects dramatically affects the results, predicting KAs at only when εF is close to a band crossing EX. For each band crossing a double KA occurs for εF=EX ω/2, where ω is the phonon energy. In particular, for a 1.2 nm metallic nanotube, we predict a KA to occur in the so-called G- peak at a doping level of about Nel/C= 0.0015 atom (εF≈ 0.1 ~eV). Furthermore, we predict that the Raman linewidth of the G- peak significantly decreases for |εF| ≥ ω/2.
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