692 research outputs found
Maximum temperature for an Ideal Gas of Kac-Moody Fermions
A lagrangian for gauge fields coupled to fermions with the Kac-Moody group as
its gauge group yields, for the pure fermions sector, an ideal gas of Kac-Moody
fermions. The canonical partition function for the case is shown to
have a maximum temperature , where is the
coupling of the super charge operator to the fermions. This result is
similar to the case of strings but unlike strings the result is obtained from a
well-defined lagrangian.Comment: Needs subeqnarray.sty; To be published in Phys. Rev. D, Dec 15, 1995.
Some typographical errors have been corrected in the revised versio
Alternative Dispute Resolution in India - ADR: status/effectiveness study
This study focuses on the effectiveness of Alternative Dispute Resolution mechanisms in India. The broad targets included (a) a comparative analysis of institutional ADRs and ad-hoc ADR, (b) cost and time benefit analysis of ADRs in comparison with adjudication through courts; (c) study of the effectiveness of pre-trial mediation centres; and (e) to make concrete suggestions. The study proves that ADR in India has not been that effective when compared to adjudication through courts. The report favored institutional ADRs given the high rate of corruption and bureaucratic hitches prevalent in ad-hoc ADRs. The study also found that pre-trial mediation centres were developing in the right track
A Unified Framework for Consensus and Synchronization on Lie Groups admitting a Bi-Invariant Metric
For a finite number of agents evolving on a Euclidean space and linked to
each other by a connected graph, the Laplacian flow that is based on the
inter-agent errors, ensures consensus or synchronization for both first and
second-order dynamics. When such agents evolve on a circle (the Kuramoto
oscillator), the flow that depends on the sinusoid of the inter-agent error
angles generalizes the same. In this work, it is shown that the Laplacian flow
and the Kuramoto oscillator are special cases of a more general theory of
consensus on Lie groups that admit bi-invariant metrics. Such a theory not only
enables generalization of these consensus and synchronization algorithms to Lie
groups but also provide insight on to the abstract group theoretic and
differential geometric properties that ensures convergence in Euclidean space
and the circle
Landau-Ginsberg Theory of Quark Confinement
We describe the SU(3) deconfinement transition using Landau-Ginsberg theory.
Drawing on perturbation theory and symmetry principles, we construct the free
energy as a function of temperature and the Polyakov loop. Once the two
adjustable parameters of the model are fixed, the pressure p, energy epsilon
and Polyakov loop expectation value P_F are calculable functions of
temperature. An excellent fit to the continuum extrapolation of lattice
thermodynamics data can be achieved. In an extended form of the model, the
glueball potential is responsible for breaking scale invariance at low
temperatures. Three parameters are required, but the glueball mass and the
gluon condensate are calculable functions of temperature, along with p, epsilon
and P_F.Comment: Lattice99(Finite Temperature and Density) <= added keywords only
change in revised version, sorry; 3 pages, LaTeX with espcrc2.sty and
epsf.tex. Talk presented at Lattice99, Pisa, 29 June - 3 July 1999, to appear
in Nucl. Phys. B (Proc.Suppl.
Organizational factors and total quality management - an empirical study
The level of awareness of Total Quality Management (TQM) has increased considerably over the last few years. Different sets of organizational requirements are prescribed by quality management gurus and practitioners for the effective practice of TQM. These requirements do not seem to have been formulated on the basis of systematic empirical research. Many researchers point out that tacit factors, e.g. employee empowerment, open culture and executive commitment, and not TQM tools and techniques alone, could drive TQM success, and that organizations would need to acquire these factors to stay successful. Many TQM advocates have also suggested that a conducive organizational environment would be essential for an effective practice of TQM. However, they did not offer any empirical evidence. There appears to be no empirical study reported in the literature that could establish a relation between TQM and organizational factors. The objective of this paper is to describe an empirical research on TQM conducted in Indian business units carried out recently by considering some organizational factors, e.g. quality of work life, organizational climate and communication. The methodology and findings are discussed in detail
The factorization method for systems with a complex action -a test in Random Matrix Theory for finite density QCD-
Monte Carlo simulations of systems with a complex action are known to be
extremely difficult. A new approach to this problem based on a factorization
property of distribution functions of observables has been proposed recently.
The method can be applied to any system with a complex action, and it
eliminates the so-called overlap problem completely. We test the new approach
in a Random Matrix Theory for finite density QCD, where we are able to
reproduce the exact results for the quark number density. The achieved system
size is large enough to extract the thermodynamic limit. Our results provide a
clear understanding of how the expected first order phase transition is induced
by the imaginary part of the action.Comment: 27 pages, 25 figure
Anomalous Chiral Symmetry Breaking above the QCD Phase Transition
We study the anomalous breaking of U_A(1) symmetry just above the QCD phase
transition for zero and two flavors of quarks, using a staggered fermion,
lattice discretization. The properties of the QCD phase transition are expected
to depend on the degree of U_A(1) symmetry breaking in the transition region.
For the physical case of two flavors, we carry out extensive simulations on a
16^3 x 4 lattice, measuring a difference in susceptibilities which is sensitive
to U_A(1) symmetry and which avoids many of the staggered fermion
discretization difficulties. The results suggest that anomalous effects are at
or below the 15% level.Comment: 10 pages including 2 figures and 1 tabl
Kosterlitz Thouless Universality in Dimer Models
Using the monomer-dimer representation of strongly coupled U(N) lattice gauge
theories with staggered fermions, we study finite temperature chiral phase
transitions in (2+1) dimensions. A new cluster algorithm allows us to compute
monomer-monomer and dimer-dimer correlations at zero monomer density (chiral
limit) accurately on large lattices. This makes it possible to show
convincingly, for the first time, that these models undergo a finite
temperature phase transition which belongs to the Kosterlitz-Thouless
universality class. We find that this universality class is unaffected even in
the large N limit. This shows that the mean field analysis often used in this
limit breaks down in the critical region.Comment: 4 pages, 4 figure
Anomaly and a QCD-like phase diagram with massive bosonic baryons
We study a strongly coupled lattice gauge theory with two flavors of
quarks, invariant under an exact symmetry which is the same as QCD with
two flavors of quarks without an anomaly. The model also contains a coupling
that can be used to break the symmetry and thus mimic the QCD
anomaly. At low temperatures and small baryon chemical potential
the model contains massless pions and massive bosonic baryons similar to QCD
with an even number of colors. In this work we study the phase
diagram of the model and show that it contains three phases : (1) A chirally
broken phase at low and , (2) a chirally symmetric baryon superfluid
phase at low and high , and (3) a symmetric phase at high . We
find that the nature of the finite temperature chiral phase transition and in
particular the location of the tricritical point that seperates the first order
line from the second order line is affected significantly by the anomaly.Comment: 22 pages, 16 figures, 5 tables, references adde
A Multi-level Algorithm for Quantum-impurity Models
A continuous-time path integral Quantum Monte Carlo method using the
directed-loop algorithm is developed to simulate the Anderson single-impurity
model in the occupation number basis. Although the method suffers from a sign
problem at low temperatures, the new algorithm has many advantages over
conventional algorithms. For example, the model can be easily simulated in the
Kondo limit without time discretization errors. Further, many observables
including the impurity susceptibility and a variety of fermionic observables
can be calculated efficiently. Finally the new approach allows us to explore a
general technique, called the multi-level algorithm, to solve the sign problem.
We find that the multi-level algorithm is able to generate an exponentially
large number of configurations with an effort that grows as a polynomial in
inverse temperature such that configurations with a positive sign dominate over
those with negative signs. Our algorithm can be easily generalized to other
multi-impurity problems.Comment: 9 pages, 8 figure
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