16,585 research outputs found
Why edge effects are important on the intrinsic loss mechanisms of graphene nanoresonators?
Molecular dynamics simulations are performed to investigate edge effects on
the quality factor of graphene nanoresonators with different edge
configurations and of various sizes. If the periodic boundary condition is
applied, very high quality factors () are obtained for all kinds
of graphene nanoresonators. However, if the free boundary condition is applied,
quality factors will be greatly reduced by two effects resulting from free
edges: the imaginary edge vibration effect and the artificial effect. Imaginary
edge vibrations will flip between a pair of doubly degenerate warping states
during the mechanical oscillation of nanoresonators. The flipping process
breaks the coherence of the mechanical oscillation of the nanoresonator, which
is the dominant mechanism for extremely low quality factors. There is an
artificial effect if the mechanical oscillation of the graphene nanoresonator
is actuated according to an artificial vibration (non-natural vibration of the
system), which slightly reduce the quality factor. The artificial effect can be
eliminated by actuating the mechanical oscillation according to a natural
vibration of the nanoresonator. Our simulations provide an explanation for the
recent experiment, where the measured quality factor is low and varies between
identical samples with free edges.Comment: accepted by J. Appl. Phy
Mechanism of phonon localized edge modes
The phonon localized edge modes are systematically studied, and two
conditions are proposed for the existence of the localized edge modes: (I)
coupling between different directions (, or ) in the interaction;
(II) different boundary conditions in three directions. The generality of these
two conditions is illustrated by different lattice structures: one-dimensional
(1D) chain, 2D square lattice, 2D graphene, 3D simple cubic lattice, 3D diamond
structure, etc; and with different potentials: valence force field model,
Brenner potential, etc.Comment: 5 pages, 8 fig
Graphene-based tortional resonator from molecular dynamics simulation
Molecular dynamics simulations are performed to study graphene-based
torsional mechanical resonators. The quality factor is calculated by
, where the frequency and life time are
obtained from the correlation function of the normal mode coordinate. Our
simulations reveal the radius-dependence of the quality factor as
, which yields a maximum value at some proper
radius . This maximum point is due to the strong boundary effect in the
torsional resonator, as disclosed by the temperature distribution in the
resonator. Resulting from the same boundary effect, the quality factor shows a
power law temperature-dependence with power factors bellow 1.0. The theoretical
results supply some valuable information for the manipulation of the quality
factor in future experimental devices based on the torsional mechanical
resonator.Comment: (accepted by EPL). New email address for Jin-Wu Jiang after
22/Nov/2011: [email protected]
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