Open AccessHigh Electronic Conductance through Double-Helix DNA Molecules with Fullerene Anchoring Groups
Author(s) -
Kathia L. Jiménez-Monroy,
Nicolas Renaud,
Jeroen Drijkoningen,
David Cortens,
Koen Schouteden,
C. Van Haesendonck,
Wanda Guedens,
Jean Manca,
Laurens D. A. Siebbeles,
Ferdinand C. Grozema,
Patrick Wagner
Publication year - 2017
Publication title -
the journal of physical chemistry a
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.756
H-Index - 235
eISSN - 1520-5215
pISSN - 1089-5639
DOI - 10.1021/acs.jpca.7b00348
Subject(s) - molecule , chemical physics , delocalized electron , dna , conductance , helix (gastropod) , materials science , fullerene , nanotechnology , chemistry , crystallography , condensed matter physics , physics , ecology , biochemistry , organic chemistry , snail , biology
Determining the mechanism of charge transport through native DNA remains a challenge as different factors such as measuring conditions, molecule conformations, and choice of technique can significantly affect the final results. In this contribution, we have used a new approach to measure current flowing through isolated double-stranded DNA molecules, using fullerene groups to anchor the DNA to a gold substrate. Measurements were performed at room temperature in an inert environment using a conductive AFM technique. It is shown that the π-stacked B-DNA structure is conserved on depositing the DNA. As a result, currents in the nanoampere range were obtained for voltages ranging between ±1 V. These experimental results are supported by a theoretical model that suggests that a multistep hopping mechanism between delocalized domains is responsible for the long-range current flow through this specific type of DNA.
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