487 research outputs found
Composite Strings in (2+1)-Dimensional Anisotropic Weakly-Coupled Yang-Mills Theory
The small-scale structure of a string connecting a pair of static sources is
explored for the weakly-coupled anisotropic SU(2) Yang-Mills theory in (2+1)
dimensions. A crucial ingredient in the formulation of the string Hamiltonian
is the phenomenon of color smearing of the string constituents. The
quark-anti-quark potential is determined. We close with some discussion of the
standard, fully Lorentz-invariant Yang-Mills theory.Comment: Some minor errors corrected, references slightly reorganized, version
to appear in Phys. Rev.
A reparametrization invariant surface ordering
We introduce a notion of a non-Abelian loop gauge field defined on points in
loop space. For this purpose we first find an infinite-dimensional tensor
product representation of the Lie algebra which is particularly suited for
fields on loop space. We define the non-Abelian Wilson surface as a `time'
ordered exponential in terms of this loop gauge field and show that it is
reparametrization invariant.Comment: 11 pages, clarifications and added ref
Simulating Stochastic Dynamics Using Large Time Steps
We present a novel approach to investigate the long-time stochastic dynamics
of multi-dimensional classical systems, in contact with a heat-bath. When the
potential energy landscape is rugged, the kinetics displays a decoupling of
short and long time scales and both
Molecular Dynamics (MD) or Monte Carlo (MC) simulations are generally
inefficient. Using a field theoretic approach, we perform analytically the
average over the short-time stochastic fluctuations. This way, we obtain an
effective theory, which generates the same long-time dynamics of the original
theory, but has a lower time resolution power. Such an approach is used to
develop an improved version of the MC algorithm, which is particularly suitable
to investigate the dynamics of rare conformational transitions. In the specific
case of molecular systems at room temperature, we show that elementary
integration time steps used to simulate the effective theory can be chosen a
factor ~100 larger than those used in the original theory. Our results are
illustrated and tested on a simple system, characterized by a rugged energy
landscape.Comment: 17 pager, 7 figure
String Tensions and Representations in Anisotropic 2+1-Dimensional Weakly-Coupled Yang-Mills Theory
In earlier papers we established quark confinement analytically in anisotropic -dimensional Yang-Mills theory with two gauge coupling constants. Here we point out a few features of the confining phase. These are: 1) the string tension in the -direction as a function of representation obeys a sine law, and 2) static adjoint sources are not confined
Fluctuations in the Ensemble of Reaction Pathways
The dominant reaction pathway (DRP) is a rigorous framework to
microscopically compute the most probable trajectories, in non-equilibrium
transitions. In the low-temperature regime, such dominant pathways encode the
information about the reaction mechanism and can be used to estimate
non-equilibrium averages of arbitrary observables. On the other hand, at
sufficiently high temperatures, the stochastic fluctuations around the dominant
paths become important and have to be taken into account. In this work, we
develop a technique to systematically include the effects of such stochastic
fluctuations, to order k_B T. This method is used to compute the probability
for a transition to take place through a specific reaction channel and to
evaluate the reaction rate
The Metric of Yang-Mills Orbit Space on the Lattice
We find coordinates, the metric tensor, the inverse metric tensor and the
Laplace-Beltrami operator for the orbit space of Hamiltonian SU(2) gauge theory
on a finite, rectangular lattice. This is done using a complete axial gauge
fixing. The Gribov problem can be completely solved, with no remaining gauge
ambiguities.Comment: Title is changed in journal. Now 19 pages, still one figure, AMSTe
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