Intermediate coherent-incoherent charge transport: DNA as a case study

TL;DR

This paper investigates intermediate charge transport in DNA molecules using B"uttiker's probe technique, revealing how sequence structure influences coherent and incoherent conduction mechanisms, with implications for understanding molecular electronics.

Contribution

It introduces a combined minimal and detailed modeling approach to analyze intermediate charge transport in DNA, highlighting the role of sequence structure and environmental effects.

Findings

Hopping conduction dominates in alternating sequences.

Stacked sequences support charge delocalization and resonant-ballistic transport.

Weak distance dependence observed in stacked DNA sequences.

Abstract

We study an intermediate quantum coherent-incoherent charge transport mechanism in metal-molecule-metal junctions using B\"uttiker's probe technique. This tool allows us to include incoherent effects in a controlled manner, and thus to study situations in which partial decoherence affects charge transfer dynamics. Motivated by recent experiments on intermediate coherent-incoherent charge conduction in DNA molecules [L. Xiang {\it et al.}, Nature Chem. 7, 221-226 (2015)], we focus on two representative structures: alternating (GC)$_n$ and stacked G$_n$C$_n$ sequences; the latter structure is argued to support charge delocalization within G segments, and thus an intermediate coherent-incoherent conduction. We begin our analysis with a highly simplified 1-dimensional tight-binding model, while introducing environmental effects through B\"uttiker's probes. This minimal model allows us to gain fundamental understanding of transport mechanisms and derive analytic results for molecular resistance in different limits. We then use a more detailed ladder-model Hamiltonian to represent double-stranded DNA structures---with environmental effects captured by B\"uttiker's probes. We find that hopping conduction dominates in alternating sequences, while in stacked sequences charge delocalization (visualized directly through the electronic density matrix) supports significant resonant-ballistic charge dynamics reflected by an even-odd effect and a weak distance dependence for resistance. Our analysis illustrates that lessons learned from minimal models are helpful for interpreting charge dynamics in DNA.