17,010 research outputs found
Surface Percolation and Growth. An alternative scheme for breaking the diffraction limit in optical patterning
A nanopatterning scheme is presented by which the structure height can be
controlled in the tens of nanometers range and the lateral resolution is a
factor at least three times better than the point spread function of the
writing beam. The method relies on the initiation of the polymerization
mediated by a very inefficient energy transfer from a fluorescent dye molecule
after single photon absorption. The mechanism has the following distinctive
steps: the dye adsorbs on the substrate surface with a higher concentration
than in the bulk, upon illumination it triggers the polymerization, then
isolated islands develop and merge into a uniform structure (percolation),
which subsequently grows until the illumination is interrupted. This
percolation mechanism has a threshold that introduces the needed nonlinearity
for the fabrication of structures beyond the diffraction limit.Comment: 10 pages, 8 figure
Effect of the number of vortices on the torque scaling in Taylor-Couette flow
Torque measurements in Taylor-Couette flow, with large radius ratio and large
aspect ratio, over a range of velocities up to a Reynolds number of 24 000 are
presented. Following a specific procedure, nine states with distinct number of
vortices along the axis were found and the aspect ratio of the vortices were
measured. The relationship between the speed and the torque for a given number
of vortices is reported. In the turbulent Taylor vortex flow regime, at
relatively high Reynolds number, a change in behaviour is observed
corresponding to intersections of the torque-speed curves for different states.
Before each intersection, the torque for a state with larger number of vortices
is higher. After each intersection, the torque for a state with larger number
of vortices is lower. The exponent, from the scaling laws of the torque, always
depends on the aspect ratio of the vortices. When the Reynolds number is
rescaled using the mean aspect ratio of the vortices, only a partial collapse
of the exponent data is found.Comment: 11 pages, 6 figure
Lattice Boltzmann Magnetohydrodynamics
Lattice gas and lattice Boltzmann methods are recently developed numerical
schemes for simulating a variety of physical systems. In this paper a new
lattice Boltzmann model for modeling two-dimensional incompressible
magnetohydrodynamics (MHD) is presented. The current model fully utilizes the
flexibility of the lattice Boltzmann method in comparison with previous lattice
gas and lattice Boltzmann
MHD models, reducing the number of moving directions from in other
models to only. To increase computational efficiency, a simple single time
relaxation rule is used for collisions, which directly controls the transport
coefficients.
The bi-directional streaming process of the particle distribution function in
this paper is similar to the original model [ H. Chen and W. H. Matthaeus,
Phys. Rev. Lett., {\bf 58}, 1845(1987), S.Chen, H.Chen, D.Mart\'{\i}nez and
W.H.Matthaeus, Phys. Rev. Lett. {\bf 67},3776 (1991)], but has been greatly
simplified, affording simpler implementation of boundary conditions and
increasing the feasibility of extension into a workable three-dimensional
model. Analytical expressions for the transport coefficients are presented.
Also, as example cases, numerical calculation for the Hartmann flow is
performed, showing a good agreement between the theoreticalComment: 45 pages, to appear in Physics of Plasma
Diffusion in infinite and semi-infinite lattices with long-range coupling
We prove that for a one-dimensional infinite lattice, with long-range
coupling among sites, the diffusion of an initial delta-like pulse in the bulk,
is ballistic at all times. We obtain a closed-form expression for the mean
square displacement (MSD) as a function of time, and show some cases including
finite range coupling, exponentially decreasing coupling and power-law
decreasing coupling. For the case of an initial excitation at the edge of the
lattice, we find an approximate expression for the MSD that predicts ballistic
behavior at long times, in agreement with numerical results.Comment: 4 pages, 5 figures, submitted for publicatio
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