46,093 research outputs found
Rotating states in driven clock- and XY-models
We consider 3D active plane rotators, where the interaction between the spins
is of XY-type and where each spin is driven to rotate. For the clock-model,
when the spins take N\gg1 possible values, we conjecture that there are two
low-temperature regimes. At very low temperatures and for small enough drift
the phase diagram is a small perturbation of the equilibrium case. At larger
temperatures the massless modes appear and the spins start to rotate
synchronously for arbitrary small drift. For the driven XY-model we prove that
there is essentially a unique translation-invariant and stationary distribution
despite the fact that the dynamics is not ergodic
A (2+1)-dimensional growth process with explicit stationary measures
We introduce a class of (2+1)-dimensional stochastic growth processes, that
can be seen as irreversible random dynamics of discrete interfaces.
"Irreversible" means that the interface has an average non-zero drift.
Interface configurations correspond to height functions of dimer coverings of
the infinite hexagonal or square lattice. The model can also be viewed as an
interacting driven particle system and in the totally asymmetric case the
dynamics corresponds to an infinite collection of mutually interacting
Hammersley processes.
When the dynamical asymmetry parameter equals zero, the
infinite-volume Gibbs measures (with given slope ) are
stationary and reversible. When , are not reversible any
more but, remarkably, they are still stationary. In such stationary states, we
find that the average height function at any given point grows linearly
with time with a non-zero speed: while the typical fluctuations of are
smaller than any power of as .
In the totally asymmetric case of and on the hexagonal lattice, the
dynamics coincides with the "anisotropic KPZ growth model" introduced by A.
Borodin and P. L. Ferrari. For a suitably chosen, "integrable", initial
condition (that is very far from the stationary state), they were able to
determine the hydrodynamic limit and a CLT for interface fluctuations on scale
, exploiting the fact that in that case certain space-time
height correlations can be computed exactly.Comment: 37 pages, 13 figures. v3: some references added, introduction
expanded, minor changes in the bul
Motion of condensates in non-Markovian zero-range dynamics
Condensation transition in a non-Markovian zero-range process is studied in
one and higher dimensions. In the mean-field approximation, corresponding to
infinite range hopping, the model exhibits condensation with a stationary
condensate, as in the Markovian case, but with a modified phase diagram. In the
case of nearest-neighbor hopping, the condensate is found to drift by a
"slinky" motion from one site to the next. The mechanism of the drift is
explored numerically in detail. A modified model with nearest-neighbor hopping
which allows exact calculation of the steady state is introduced. The steady
state of this model is found to be a product measure, and the condensate is
stationary.Comment: 31 pages, 9 figure
Metastability of Queuing Networks with Mobile Servers
We study symmetric queuing networks with moving servers and FIFO service
discipline. The mean-field limit dynamics demonstrates unexpected behavior
which we attribute to the meta-stability phenomenon. Large enough finite
symmetric networks on regular graphs are proved to be transient for arbitrarily
small inflow rates. However, the limiting non-linear Markov process possesses
at least two stationary solutions. The proof of transience is based on
martingale techniques
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