2,233 research outputs found
Critical couplings and string tensions via lattice matching of RG decimations
We calculate critical couplings and string tensions in SU(2) and SU(3) pure
lattice gauge theory by a simple and inexpensive technique of two-lattice
matching of RG block transformations. The transformations are potential moving
decimations generating plaquette actions with large number of group characters
and exhibit rapid approach to a unique renormalized trajectory. Fixing the
critical coupling at one value of temporal lattice length
by MC simulation, the critical couplings for any other value of
are then obtained by lattice matching of the block decimations. We
obtain values over the range and find
agreement with MC simulation results to within a few percent in all cases. A
similar procedure allows the calculation of string tensions with similarly good
agreement with MC data.Comment: 12 pages, Latex, 1 figur
Quark Confinement and the Renormalization Group
Recent approaches to quark confinement are reviewed, with an emphasis on
their connection to renormalization group methods. Basic concepts related to
confinement are introduced: the string tension, Wilson loops and Polyakov
lines, string breaking, string tension scaling laws, center symmetry breaking,
and the deconfinement transition at non-zero temperature. Current topics
discussed include confinement on , the real-space
renormalization group, the functional renormalization group, and the
Schwinger-Dyson equation approach to confinement.Comment: 22 pages; report from the INT Workshop "New applications of the
renormalization group in nuclear, particle, and condensed matter physics",
held February 22-26 201
Mixed Model of Induced QCD
The problems with the symmetry breaking in the induced QCD are
analyzed. We compute the Wilson loops in the strong coupling phase, but we do
not find the symmetry breaking, for arbitrary potential. We suggest to
bypass this problem by adding to the model a heavy fermion field in a
fundamental representation of . Remarkably, the model still can be
solved exactly by the Rieman-Hilbert method, for arbitrary number of
flavors. At there is a new regime, with two
vacuum densities. The symmetry breaking density satisfies the linear
integral equation, with the kernel, depending upon the old density. The
symmetry breaking requires certain eigenvalue condition, which takes some extra
parameter adjustment of the scalar potential.Comment: 14 pages, Latex, no figures, ( after final debugging
1/N Expansion and Particle Spectrum in Induced QCD
We study the 1/N expansion in the recently proposed model of the lattice
gauge theory induced by heavy scalar field in adjoint representation. In the
first approximation the fluctuations of the density of eigenvalues of the
scalar field are Gaussian, so that the scalar glueball spectrum is defined from
the corresponding linear wave equation
Bose Condensation and Symmetry Breaking in the Mixed Model of Induced QCD
The mixed model of the large induced QCD, with flavors of
heavy fermions in fundamental representation, is solved in the local limit. The
symmetry is broken spontaneously in the large limit, evading the
Elitzur "no-go" theorem. As a result of this symmetry breaking, there is the
Bose condensate of the eigenvalues of the scalar field, proportional to . This condensate leads to the mass unit, which goes to zero as
fractional power of , thus defining the new kind of the local
limit of this lattice theory. There is a strong coupling region below this mass
scale, which revives the hopes of induction of realistic QCD.Comment: 16 pages, Latex, no figures, PUPT-134
Two-dimensional Born-Infeld gauge theory: spectrum, string picture and large-N phase transition
We analyze U(N) Born-Infeld gauge theory in two spacetime dimensions. We
derive the exact energy spectrum on the circle and show that it reduces to N
relativistic fermions on a dual space. This contrasts to the Yang-Mills case
that reduces to nonrelativistic fermions. The theory admits a string theory
interpretation, analogous to the one for ordinary Yang-Mills, but with higher
order string interactions. We also demonstrate that the partition function on
the sphere exhibits a large-N phase transition in the area and calculate the
critical area. The limit in which the dimensionless coupling of the theory goes
to zero corresponds to massless fermions, admits a perturbatively exact free
string interpretation and exhibits no phase transition.Comment: 19 page
Finite-temperature phase diagram of nonmagnetic impurities in high-temperature superconductors using a d=3 tJ model with quenched disorder
We study a quenched disordered d=3 tJ Hamiltonian with static vacancies as a
model of nonmagnetic impurities in high-Tc materials. Using a position-space
renormalization-group approach, we calculate the evolution of the
finite-temperature phase diagram with impurity concentration p, and find
several features with close experimental parallels: away from half-filling we
see the rapid destruction of a spin-singlet phase (analogous to the
superconducting phase in cuprates) which is eliminated for p > 0.05; in the
same region for these dilute impurity concentrations we observe an enhancement
of antiferromagnetism. The antiferromagnetic phase near half-filling is robust
against impurity addition, and disappears only for p > 0.40.Comment: 5 pages, 4 figures; replaced with published versio
High-Precision Thermodynamic and Critical Properties from Tensor Renormalization-Group Flows
The recently developed tensor renormalization-group (TRG) method provides a
highly precise technique for deriving thermodynamic and critical properties of
lattice Hamiltonians. The TRG is a local coarse-graining transformation, with
the elements of the tensor at each lattice site playing the part of the
interactions that undergo the renormalization-group flows. These tensor flows
are directly related to the phase diagram structure of the infinite system,
with each phase flowing to a distinct surface of fixed points. Fixed-point
analysis and summation along the flows give the critical exponents, as well as
thermodynamic functions along the entire temperature range. Thus, for the
ferromagnetic triangular lattice Ising model, the free energy is calculated to
better than 10^-5 along the entire temperature range. Unlike previous
position-space renormalization-group methods, the truncation (of the tensor
index range D) in this general method converges under straightforward and
systematic improvements. Our best results are easily obtained with D = 24,
corresponding to 4624-dimensional renormalization-group flows.Comment: 6 pages, 5 figure
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