Direct measurement of electrical transport through DNA molecules

Abstract

Attempts to infer DNA electron transfer from fluorescence quenching measurements^{1,2,3,4,5,6,7,8,9} on DNA strands doped with donor and acceptor molecules have spurred intense debate^10,11 over the question of whether or not this important biomolecule is able to conduct electrical charges. More recently, first electrical transport measurements on micrometre-long DNA ‘ropes’¹², and also on large numbers of DNA molecules in films¹³, have indicated that DNA behaves as a good linear conductor. Here we present measurements of electrical transport through individual 10.4-nm-long, double-stranded poly(G)-poly(C) DNA molecules connected to two metal nanoelectrodes, that indicate, by contrast, large-bandgap semiconducting behaviour. We obtain nonlinear current–voltage curves that exhibit a voltage gap at low applied bias. This is observed in air as well as in vacuum down to cryogenic temperatures. The voltage dependence of the differential conductance exhibits a peak structure, which is suggestive of the charge carrier transport being mediated by the molecular energy bands of DNA.