Defective carbon nanotubes for single-molecule sensing

Zeila Zanolli; J. C. Charlier

doi:10.1103/PhysRevB.80.155447

Defective carbon nanotubes for single-molecule sensing

Zeila Zanolli^*
, J. C. Charlier

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

The sensing ability of metallic carbon nanotubes toward various gas species (NO2, NH3, CO, H2 O, and CO2) is investigated via ab initio calculations and Nonequilibrium Green's Functions technique, focusing on the salient features of the interaction between molecules and oxygenated-defective tubes. As the adsorption/desorption of molecules induces modulations on the electrical conductivity of the tube, the computation of the electron quantum conductance can be used to predict gas detection. Indeed, the analysis of the conductance curve in a small energy range around the Fermi energy reveal that oxygenated-defective nanotubes are sensitive to NO2, NH3, CO, and H2 O, but not to CO2. Molecular selectivity can also be provided by the nature of the charge transfer.

Original language	English
Article number	155447
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	80
Issue number	15
DOIs	https://doi.org/10.1103/PhysRevB.80.155447
Publication status	Published - 26 Oct 2009
Externally published	Yes

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title = "Defective carbon nanotubes for single-molecule sensing",

abstract = "The sensing ability of metallic carbon nanotubes toward various gas species (NO2, NH3, CO, H2 O, and CO2) is investigated via ab initio calculations and Nonequilibrium Green's Functions technique, focusing on the salient features of the interaction between molecules and oxygenated-defective tubes. As the adsorption/desorption of molecules induces modulations on the electrical conductivity of the tube, the computation of the electron quantum conductance can be used to predict gas detection. Indeed, the analysis of the conductance curve in a small energy range around the Fermi energy reveal that oxygenated-defective nanotubes are sensitive to NO2, NH3, CO, and H2 O, but not to CO2. Molecular selectivity can also be provided by the nature of the charge transfer.",

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AU - Charlier, J. C.

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N2 - The sensing ability of metallic carbon nanotubes toward various gas species (NO2, NH3, CO, H2 O, and CO2) is investigated via ab initio calculations and Nonequilibrium Green's Functions technique, focusing on the salient features of the interaction between molecules and oxygenated-defective tubes. As the adsorption/desorption of molecules induces modulations on the electrical conductivity of the tube, the computation of the electron quantum conductance can be used to predict gas detection. Indeed, the analysis of the conductance curve in a small energy range around the Fermi energy reveal that oxygenated-defective nanotubes are sensitive to NO2, NH3, CO, and H2 O, but not to CO2. Molecular selectivity can also be provided by the nature of the charge transfer.

AB - The sensing ability of metallic carbon nanotubes toward various gas species (NO2, NH3, CO, H2 O, and CO2) is investigated via ab initio calculations and Nonequilibrium Green's Functions technique, focusing on the salient features of the interaction between molecules and oxygenated-defective tubes. As the adsorption/desorption of molecules induces modulations on the electrical conductivity of the tube, the computation of the electron quantum conductance can be used to predict gas detection. Indeed, the analysis of the conductance curve in a small energy range around the Fermi energy reveal that oxygenated-defective nanotubes are sensitive to NO2, NH3, CO, and H2 O, but not to CO2. Molecular selectivity can also be provided by the nature of the charge transfer.

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Defective carbon nanotubes for single-molecule sensing

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