Ernane de Freitas Martins scite author profile

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 QM/MM and non-equilibrium Green's functions 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.

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The role of water on the electronic transport in graphene nanogap devices designed for DNA sequencing

Martins

Amorim

Feliciano

et al. 2020

Carbon

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Unraveling the Mechanism of the Cinchoninium Ion Asymmetric Phase-Transfer-Catalyzed Alkylation Reaction

Martins

Pliego

2013

ACS Catal.

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The mechanism of the alkylation reaction of the indanone anion through asymmetric phase-transfer catalysis has been unraveled by density functional theory calculations. Our results point out that the present view of the asymmetry induction mechanism determined by hydrogen bond and π–π stacking interactions is not correct. Rather, stabilization of the main reaction pathway takes place through both the hydrogen bond and electrostatic interaction involving the leaving chloride anion.

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Simulating DNA Chip Design Using All-Electronic Graphene-Based Substrates

2019

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In this paper, we present a theoretical investigation of an all-electronic biochip based on graphene to detect DNA including a full dynamical treatment for the environment. Our proposed device design is based on the changes in the electronic transport properties of graphene interacting with DNA strands under the effect of the solvent. To investigate these systems, we applied a hybrid methodology, combining quantum and classical mechanics (QM/MM) coupled to non-equilibrium Green’s functions, allowing for the calculations of electronic transport. Our results show that the proposed device has high sensitivity towards the presence of DNA, and, combined with the presence of a specific DNA probe in the form of a single-strand, it presents good selectivity towards specific nucleotide sequences.

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