Interaction Potential of Open Carbon Nanotube with Natural Gas Molecular Components

Egor Tarasov

doi:10.4028/www.scientific.net/KEM.685.534

Paper Titles

Morphology of Aluminum Nanopowder Combustion Products in a Magnetic Field in Air
p.516

The Influence of Aluminium Nanopowder Density on the Structure and Properties of its Combustion Products in Air
p.521

Influence of Severe Plastic Deformation on Physicomechanical Properties of Ti-40 mas % Nb Alloy
p.525

Developing Nanomaterials with Given Properties Based on Aluminum Oxyhydroxide
p.530

Interaction Potential of Open Carbon Nanotube with Natural Gas Molecular Components
p.534

Use of Zinc Oxide Nanopowder as an Additive in a Tribotechnical Composite Based on Refractory Metal Disulfide
p.539

Strains Determination at the Joints of Cylindrical Glass-Metal Composite Shell Layers
p.543

Influence of Filling Agent Quantity on Characteristics of Polymeric Composites
p.548

Microwave Composite Absorbers Based on Barium Hexaferrite/Carbon Nanotubes for 0.01-18 GHz Applications
p.553

HomeKey Engineering MaterialsKey Engineering Materials Vol. 685Interaction Potential of Open Carbon Nanotube with...

Interaction Potential of Open Carbon Nanotube with Natural Gas Molecular Components

Abstract:

In this paper presents the study of the process of interaction between helium (He) and methane (СH₄) molecules and the energy barrier created by a single-layer carbon nanotube. The interaction potential fields for the case of a tube as a nano-scale object interacting with single molecules or atoms were determined. Calculations show the dependence of molecular velocity within the symmetry axis of a single-layer carbon nanotube on the axial coordinate. The influence of the tube radius on the character of molecular passage through the open tube is considered.

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High Technology: Research and Applications 2015

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Key Engineering Materials (Volume 685)

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534-538

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.685.534

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Online since:

February 2016

Authors:

Egor Tarasov

Keywords:

Carbon Nanotubes, Energy Barrier, Molecular Ballistics

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References

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