8,384 research outputs found
Periodic ripples in suspended graphene
We study the mechanism of wrinkling of suspended graphene, by means of
atomistic simulations. We argue that the structural instability under edge
compression is the essential physical reason for the formation of periodic
ripples in graphene. The ripple wavelength and out-of-plane amplitude are found
to obey 1/4-power scaling laws with respect to edge compression. Our results
also show that parallel displacement of the clamped boundaries can induce
periodic ripples, with oscillation amplitude roughly proportional to the 1/4
power of edge displacement. The results are fundamental to graphene's
applications in electronics.Comment: 5 Figure
How Stress Can Reduce Dissipation in Glasses
We propose that stress can decrease the internal friction of amorphous
solids, either by increasing the potential barriers of defects, thus reducing
their tunneling and thermal activation that produce loss, or by decreasing the
coupling between defects and phonons. This stress can be from impurities,
atomic bonding constraints, or externally applied stress. Externally applied
stress also reduces mechanical loss through dissipation dilution. Our results
are consistent with the experiments, and predict that stress could
substantially reduce dielectric loss and increase the thermal conductivity.Comment: 9 pages, 7 figure
Mechanical properties of carbynes investigated by ab initio total-energy calculations
As sp carbon chains (carbynes) are relatively rigid molecular objects, can we
exploit them as construction elements in nanomechanics? To answer this
question, we investigate their remarkable mechanical properties by ab-initio
total-energy simulations. In particular, we evaluate their linear response to
small longitudinal and bending deformations and their failure limits for
longitudinal compression and elongation.Comment: 6 pages, 4 figures, 1 tabl
Pseudomagnetic fields and ballistic transport in a suspended graphene sheet
We study a suspended graphene sheet subject to the electric field of a gate
underneath. We compute the elastic deformation of the sheet and the
corresponding effective gauge field, which modifies the electronic transport.
In a clean system the two-terminal conductance of the sample is reduced below
the ballistic limit and is almost totally suppressed at low carrier
concentrations in samples under tension. Residual disorder restores a small
finite conductivity.Comment: 4 page
Impact of elasticity on the piezoresponse of adjacent ferroelectric domains investigated by scanning force microscopy
As a consequence of elasticity, mechanical deformations of crystals occur on
a length scale comparable to their thickness. This is exemplified by applying a
homogeneous electric field to a multi-domain ferroelectric crystal: as one
domain is expanding the adjacent ones are contracting, leading to clamping at
the domain boundaries. The piezomechanically driven surface corrugation of
micron-sized domain patterns in thick crystals using large-area top electrodes
is thus drastically suppressed, barely accessible by means of piezoresponse
force microscopy
Modeling the buckling and delamination of thin films
I study numerically the problem of delamination of a thin film elastically
attached to a rigid substrate. A nominally flat elastic thin film is modeled
using a two-dimensional triangular mesh. Both compression and bending
rigidities are included to simulate compression and bending of the film. The
film can buckle (i.e., abandon its flat configuration) when enough compressive
strain is applied. The possible buckled configurations of a piece of film with
stripe geometry are investigated as a function of the compressive strain. It is
found that the stable configuration depends strongly on the applied strain and
the Poisson ratio of the film. Next, the film is considered to be attached to a
rigid substrate by springs that can break when the detaching force exceeds a
threshold value, producing the partial delamination of the film. Delamination
is induced by a mismatch of the relaxed configurations of film and substrate.
The morphology of the delaminated film can be followed and compared with
available experimental results as a function of model parameters.
`Telephone-cord', polygonal, and `brain-like' patterns qualitatively similar to
experimentally observed configurations are obtained in different parameter
regions. The main control parameters that select the different patterns are the
mismatch between film and substrate and the degree of in-plane relaxation
within the unbuckled regions.Comment: 8 pages, 10 figure
- âŠ