Charge transfer along DNA dimers, trimers and polymers

Abstract

The transfer of electrons and holes along DNA dimers, trimers and polymers is described at the base-pair level, using the relevant on-site energies of the base-pairs and the hopping parameters between successive base-pairs. The temporal and spatial evolution of carriers along a N base-pair DNA segment is determined, solving a system of N coupled differential equations. Useful physical quantities are calculated including the pure mean carrier transfer rate k, the inverse decay length β used for exponential fit (k = k0 exp(-β d)) of the transfer rate as a function of the charge transfer distance d = N × 3.4 and the exponent η used for a power law fit (k = k0' N-η) of the transfer rate as function of the number of monomers N. Among others, the electron and hole transfer along the polymers poly(dG)-poly(dC), poly(dA)-poly(dT), GCGCGC..., ATATAT... is studied. β (η) falls in the range ≈ 0.2 - 2 -1 (1.7 - 17), k0 (k0') is usually ≈ 10-2-10-1 ( 10-2-10-1) PHz although, generally, it falls in the wider range ≈ 10-4-10 (10-4-103) PHz. The results are compared with past predictions and experiments. Our approach illustrates to which extent a specific DNA segment can serve as an efficient medium for charge transfer.