posted on 2018-03-05, 00:00authored byJariyanee Prasongkit, Ernane de Freitas Martins, Fábio A.
L. de Souza, Wanderlã L. Scopel, Rodrigo G. Amorim, Vittaya Amornkitbamrung, Alexandre R. Rocha, Ralph H. Scheicher
Topological
line defects in graphene represent an ideal way to
produce highly controlled structures with reduced dimensionality that
can be used in electronic devices. In this work, we propose using
extended line defects in graphene to improve nucleobase selectivity
in nanopore-based DNA sequencing devices. We use a combination of
quantum mechanics/molecular mechanics and nonequilibrium Green’s
function methods to investigate the conductance modulation, fully
accounting for solvent effects. By sampling over a large number of
different orientations generated from molecular dynamics simulations,
we theoretically demonstrate that distinguishing between the four
nucleobases using line defects in a graphene-based electronic device
appears possible. The changes in conductance are associated with transport
across specific molecular states near the Fermi level and their coupling
to the pore. Through the application of a specifically tuned gate
voltage, such a device would be able to discriminate the four types
of nucleobases more reliably than that of graphene sensors without
topological line defects.