12 research outputs found
Computational study of the thermal conductivity in defective carbon nanostructures
We use non-equilibrium molecular dynamics simulations to study the adverse
role of defects including isotopic impurities on the thermal conductivity of
carbon nanotubes, graphene and graphene nanoribbons. We find that even in
structurally perfect nanotubes and graphene, isotopic impurities reduce thermal
conductivity by up to one half by decreasing the phonon mean free path. An even
larger thermal conductivity reduction, with the same physical origin, occurs in
presence of structural defects including vacancies and edges in narrow graphene
nanoribbons. Our calculations reconcile results of former studies, which
differed by up to an order of magnitude, by identifying limitations of various
computational approaches
Atomistic potential for graphene and other sp carbon systems
We introduce a torsional force field for sp carbon to augment an in-plane
atomistic potential of a previous work (Kalosakas et al, J. Appl. Phys. {\bf
113}, 134307 (2013)) so that it is applicable to out-of-plane deformations of
graphene and related carbon materials. The introduced force field is fit to
reproduce DFT calculation data of appropriately chosen structures. The aim is
to create a force field that is as simple as possible so it can be efficient
for large scale atomistic simulations of various sp carbon structures
without significant loss of accuracy. We show that the complete proposed
potential reproduces characteristic properties of fullerenes and carbon
nanotubes. In addition, it reproduces very accurately the out-of-plane ZA and
ZO modes of graphene's phonon dispersion as well as all phonons with
frequencies up to 1000~cm.Comment: 9 pages, 6 figure
Vertebral osteomyelitis and native valve endocarditis due to Staphylococcus simulans: a case report
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Atomistic potential for graphene and other sp2 carbon systems
We introduce a torsional force field for sp2 carbon to augment an in-plane atomistic potential of a previous work (Kalosakas et al, J. Appl. Phys. 113, 134307 (2013)) so that it is applicable to out-of-plane deformations of graphene and related carbon materials. The introduced force field is fit to reproduce DFT calculation data of appropriately chosen structures. The aim is to create a force field that is as simple as possible so it can be efficient for large scale atomistic simulations of various sp2 carbon structures without significant loss of accuracy. We show that the complete proposed potential reproduces characteristic properties of fullerenes and carbon nanotubes. In addition, it reproduces very accurately the out-of-plane ZA and ZO modes of graphene’s phonon dispersion as well as all phonons with frequencies up to 1000 cm−1.</div