Transport properties, spectral function, and optical conductivity of the adiabatic one-dimensional Su-Schrieffer-Heeger model are studied with particular emphasis on the model parameters suitable for rubrene single-crystal-based field effect transistors. We show that the mobility, calculated by using the Kubo formula for conductivity including vertex renormalization, vanishes unless we introduce an ad hoc broadening of the system energy levels. Furthermore, the apparent contradiction between angle-resolved photoemission data and transport properties is clarified by studying the behavior of the spectral function. Finally, a peak in the optical conductivity at very low energy is obtained and discussed in connection with the available experimental data for rubrene-based devices.
Transport properties and optical conductivity of the adiabatic Su-Schrieffer-Heeger model: A showcase study for rubrene-based field effect transistors
Cataudella V;De Filippis G;Perroni CA
2011
Abstract
Transport properties, spectral function, and optical conductivity of the adiabatic one-dimensional Su-Schrieffer-Heeger model are studied with particular emphasis on the model parameters suitable for rubrene single-crystal-based field effect transistors. We show that the mobility, calculated by using the Kubo formula for conductivity including vertex renormalization, vanishes unless we introduce an ad hoc broadening of the system energy levels. Furthermore, the apparent contradiction between angle-resolved photoemission data and transport properties is clarified by studying the behavior of the spectral function. Finally, a peak in the optical conductivity at very low energy is obtained and discussed in connection with the available experimental data for rubrene-based devices.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.