The chiral massive fermions in the graphitic wormhole

The graphitic wormhole appears at the center of physical interest because of its interesting properties which can remotely resemble the concept of the space wormhole. Apart from the usual applications of the carbon nanostructures like the electronic computer devices, it seems to be a good material f...

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Published in:Journal of physics. Conference series 2014-11, Vol.563 (1), p.12027-8
Main Author: Smotlacha, Jan
Format: Article
Language:English
Subjects:
Bridges (structures)
Carbon
Electronic devices
Electronic structure
Electronics
Fermions
Joining
Nanostructure
Physics
Spin-orbit interactions
Wormholes
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description The graphitic wormhole appears at the center of physical interest because of its interesting properties which can remotely resemble the concept of the space wormhole. Apart from the usual applications of the carbon nanostructures like the electronic computer devices, it seems to be a good material for the accumulation of the electric charge and different kinds of molecules, e.g. the hydrogen molecules which enables using this material for the storage of the new kinds of fuel. Here, we present the electronic structure of this material and its possibly significant derivate - the perturbed wormhole. Next, the influence of some additional factors on the electronic structure like the changes of the Fermi velocity close to the wormhole bridge as well as the the spin-orbit interaction will be investigated. On this base, we predict the massive chiral fermions in the connecting wormhole nanotube.
doi_str_mv 10.1088/1742-6596/563/1/012027
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subjects Bridges (structures)
Carbon
Electronic devices
Electronic structure
Electronics
Fermions
Joining
Nanostructure
Physics
Spin-orbit interactions
Wormholes
title The chiral massive fermions in the graphitic wormhole
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