Field Effect and Local Gating in Nitrogen-Terminated Nanopores (NtNP) and Nanogaps (NtNG) in Graphene

Functionalization of electrodes is a wide-used strategy in various applications ranging from single-molecule sensing and protein sequencing, to ion trapping, to desalination. We demonstrate, employing non-equilibrium Green ' s function formalism combined with density functional theory, that single-species (N, H, S, Cl, F) termination of graphene nanogap electrodes results in a strong in-gap electrostatic field, induced by species-dependent dipoles formed at the electrode ends. Consequently, the field increases or decreases electronic transport through a molecule (benzene) placed in the nanogap by shifting molecular levels by almost 2 eV in respect to the electrode Fermi level via a field effect akin to the one used for field-effect transistors. We also observed the local gating in graphene nanopores terminated with different single-species atoms. Nitrogen-terminated nanogaps (NtNGs) and nanopores (NtNPs) show the strongest effect. The in-gap potential can be transformed from a plateau-...

Keywords:

termination / sensors / graphene / field effect / DFT plus NEGF

Source:
Chemphyschem, 2021, 22, 3, 336-341

Publisher:

Wiley-V C H Verlag Gmbh, Weinheim

Funding / projects:

Swiss National Science Foundation (SCOPES project)Swiss National Science Foundation (SNSF) [152406]
FP7-NMP, project acronym nanoDNAsequencing [GA214840]
Ministry of Education, Science and Technological Development, Republic of Serbia, Grant no. 200053 (University of Belgrade, Institute for Multidisciplinary Research) (RS-200053)
Ministry of Education, Science and Technological Development, Republic of Serbia, Grant no. 200017 (University of Belgrade, Institute of Nuclear Sciences 'Vinča', Belgrade-Vinča) (RS-200017)
Ministry of Education, Science and Technological Development, Republic of Serbia, Grant no. 200026 (University of Belgrade, Institute of Chemistry, Technology and Metallurgy - IChTM) (RS-200026)

DOI: 10.1002/cphc.202000771

ISSN: 1439-4235

PubMed: 33245835

WoS: 000599079400001

Scopus: 2-s2.0-85097555438

[ Google Scholar ]


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	3

TY  - JOUR
AU  - Đurišić, Ivana
AU  - Dražić, Miloš
AU  - Tomović, Aleksandar
AU  - Spasenović, Marko
AU  - Šljivančanin, Zeljko
AU  - Jovanović, Vladimir
AU  - Žikić, Radomir
PY  - 2021
UR  - http://rimsi.imsi.bg.ac.rs/handle/123456789/1405
AB  - Functionalization of electrodes is a wide-used strategy in various applications ranging from single-molecule sensing and protein sequencing, to ion trapping, to desalination. We demonstrate, employing non-equilibrium Green ' s function formalism combined with density functional theory, that single-species (N, H, S, Cl, F) termination of graphene nanogap electrodes results in a strong in-gap electrostatic field, induced by species-dependent dipoles formed at the electrode ends. Consequently, the field increases or decreases electronic transport through a molecule (benzene) placed in the nanogap by shifting molecular levels by almost 2 eV in respect to the electrode Fermi level via a field effect akin to the one used for field-effect transistors. We also observed the local gating in graphene nanopores terminated with different single-species atoms. Nitrogen-terminated nanogaps (NtNGs) and nanopores (NtNPs) show the strongest effect. The in-gap potential can be transformed from a plateau-like to a saddle-like shape by tailoring NtNG and NtNP size and termination type. In particular, the saddle-like potential is applicable in single-ion trapping and desalination devices.
PB  - Wiley-V C H Verlag Gmbh, Weinheim
T2  - Chemphyschem
T1  - Field Effect and Local Gating in Nitrogen-Terminated Nanopores (NtNP) and Nanogaps (NtNG) in Graphene
EP  - 341
IS  - 3
SP  - 336
VL  - 22
DO  - 10.1002/cphc.202000771
ER  -

@article{
author = "Đurišić, Ivana and Dražić, Miloš and Tomović, Aleksandar and Spasenović, Marko and Šljivančanin, Zeljko and Jovanović, Vladimir and Žikić, Radomir",
year = "2021",
abstract = "Functionalization of electrodes is a wide-used strategy in various applications ranging from single-molecule sensing and protein sequencing, to ion trapping, to desalination. We demonstrate, employing non-equilibrium Green ' s function formalism combined with density functional theory, that single-species (N, H, S, Cl, F) termination of graphene nanogap electrodes results in a strong in-gap electrostatic field, induced by species-dependent dipoles formed at the electrode ends. Consequently, the field increases or decreases electronic transport through a molecule (benzene) placed in the nanogap by shifting molecular levels by almost 2 eV in respect to the electrode Fermi level via a field effect akin to the one used for field-effect transistors. We also observed the local gating in graphene nanopores terminated with different single-species atoms. Nitrogen-terminated nanogaps (NtNGs) and nanopores (NtNPs) show the strongest effect. The in-gap potential can be transformed from a plateau-like to a saddle-like shape by tailoring NtNG and NtNP size and termination type. In particular, the saddle-like potential is applicable in single-ion trapping and desalination devices.",
publisher = "Wiley-V C H Verlag Gmbh, Weinheim",
journal = "Chemphyschem",
title = "Field Effect and Local Gating in Nitrogen-Terminated Nanopores (NtNP) and Nanogaps (NtNG) in Graphene",
pages = "341-336",
number = "3",
volume = "22",
doi = "10.1002/cphc.202000771"
}

Đurišić, I., Dražić, M., Tomović, A., Spasenović, M., Šljivančanin, Z., Jovanović, V.,& Žikić, R.. (2021). Field Effect and Local Gating in Nitrogen-Terminated Nanopores (NtNP) and Nanogaps (NtNG) in Graphene. in Chemphyschem
Wiley-V C H Verlag Gmbh, Weinheim., 22(3), 336-341.
https://doi.org/10.1002/cphc.202000771

Đurišić I, Dražić M, Tomović A, Spasenović M, Šljivančanin Z, Jovanović V, Žikić R. Field Effect and Local Gating in Nitrogen-Terminated Nanopores (NtNP) and Nanogaps (NtNG) in Graphene. in Chemphyschem. 2021;22(3):336-341.
doi:10.1002/cphc.202000771 .

Đurišić, Ivana, Dražić, Miloš, Tomović, Aleksandar, Spasenović, Marko, Šljivančanin, Zeljko, Jovanović, Vladimir, Žikić, Radomir, "Field Effect and Local Gating in Nitrogen-Terminated Nanopores (NtNP) and Nanogaps (NtNG) in Graphene" in Chemphyschem, 22, no. 3 (2021):336-341,
https://doi.org/10.1002/cphc.202000771 . .