posted on 2017-10-10, 00:00authored byLee E. Korshoj, Sepideh Afsari, Anushree Chatterjee, Prashant Nagpal
Electronic conduction or charge transport
through single molecules
depends primarily on molecular structure and anchoring groups and
forms the basis for a wide range of studies from molecular electronics
to DNA sequencing. Several high-throughput nanoelectronic methods
such as mechanical break junctions, nanopores, conductive atomic force
microscopy, scanning tunneling break junctions, and static nanoscale
electrodes are often used for measuring single-molecule conductance.
In these measurements, “smearing” due to conformational
changes and other entropic factors leads to large variances in the
observed molecular conductance, especially in individual measurements.
Here, we show a method for characterizing smear in single-molecule
conductance measurements and demonstrate how binning measurements
according to smear can significantly enhance the use of individual
conductance measurements for molecular recognition. Using quantum
point contact measurements on single nucleotides within DNA macromolecules,
we demonstrate that the distance over which molecular junctions are
maintained is a measure of smear, and the resulting variance in unbiased
single measurements depends on this smear parameter. Our ability to
identify individual DNA nucleotides at 20× coverage increases
from 81.3% accuracy without smear analysis to 93.9% with smear characterization
and binning (SCRIB). Furthermore, merely 7 conductance measurements
(7× coverage) are needed to achieve 97.8% accuracy for DNA nucleotide
recognition when only low molecular smear measurements are used, which
represents a significant improvement over contemporary sequencing
methods. These results have important implications in a broad range
of molecular electronics applications from designing robust molecular
switches to nanoelectronic DNA sequencing.