Multiple-charge transfer and trapping in DNA dimers

TL;DR

This study models charge transfer in DNA dimers, revealing how Coulomb interactions, environmental dissipation, and bond interactions influence transfer rates, including conditions for pair transfer and charge trapping.

Contribution

It introduces a detailed model incorporating Coulomb matrix elements and environmental effects, analyzing their impact on charge transfer dynamics in DNA dimers.

Findings

Transfer rates are higher for two charges than one in certain regimes.

Charge transfer can be suppressed or oscillatory depending on bath type and parameters.

Bond-bond interaction W modulates transfer rate depending on Coulomb repulsion.

Abstract

We investigate the charge transfer characteristics of one and two excess charges in a DNA base-pair dimer using a model Hamiltonian approach. The electron part comprises diagonal and off-diagonal Coulomb matrix elements such a correlated hopping and the bond-bond interaction, which were recently calculated by Starikov [E. B. Starikov, Phil. Mag. Lett. {\bf 83}, 699 (2003)] for different DNA dimers. The electronic degrees of freedom are coupled to an ohmic or a super-ohmic bath serving as dissipative environment. We employ the numerical renormalization group method in the nuclear tunneling regime and compare the results to Marcus theory for the thermal activation regime. For realistic parameters, the rate that at least one charge is transferred from the donor to the acceptor in the subspace of two excess electrons significantly exceeds the rate in the single charge sector. Moreover, the dynamics is strongly influenced by the Coulomb matrix elements. We find sequential and pair transfer as well as a regime where both charges remain self-trapped. The transfer rate reaches its maximum when the difference of the on-site and inter-site Coulomb matrix element is equal to the reorganization energy which is the case in a GC-GC dimer. Charge transfer is completely suppressed for two excess electrons in AT-AT in an ohmic bath and replaced by damped coherent electron-pair oscillations in a super-ohmic bath. A finite bond-bond interaction $W$ alters the transfer rate: it increases as function of $W$ when the effective Coulomb repulsion exceeds the reorganization energy (inverted regime) and decreases for smaller Coulomb repulsion.