Localization of Large Polarons in the Disordered Holstein Model

Abstract

We solve the disordered Holstein model via the DMRG method to investigate the combined roles of electron-phonon coupling and disorder on the localization of a single charge or exciton. The parameter regimes chosen, namely the adiabatic regime, ω/4t0 = ω' < 1, and the `large' polaron regime, λ < 1, are applicable to most conjugated polymers. We show that as a consequence of the polaron effective mass diverging in the adiabatic limit (defined as ω' 0 subject to fixed λ) self-localized, symmetry breaking solutions are predicted by the quantum Holstein model for infinitesimal disorder -- in complete agreement with the predictions of the Born-Oppenheimer Holstein model. For other parts of the (ω', λ) parameter space, however, self-localized Born-Oppenheimer solutions are not expected. If ω' is not small enough and λ is not large enough, then the polaron is predominately localized by Anderson disorder, albeit more than for a free particle, because of the enhanced effective mass. Alternatively, for very small electron-nuclear coupling (λ 1) the disorder-induced localization length is always smaller than the classical polaron size, 2/λ, so that disorder always dominates. We comment on the implication of our results on the electronic properties of conjugated polymers.