11,627 research outputs found
QCD Strings as Constrained Grassmannian Sigma Model:
We present calculations for the effective action of string world sheet in R3
and R4 utilizing its correspondence with the constrained Grassmannian sigma
model. Minimal surfaces describe the dynamics of open strings while harmonic
surfaces describe that of closed strings. The one-loop effective action for
these are calculated with instanton and anti-instanton background, reprsenting
N-string interactions at the tree level. The effective action is found to be
the partition function of a classical modified Coulomb gas in the confining
phase, with a dynamically generated mass gap.Comment: 22 pages, Preprint: SFU HEP-116-9
A New Approach to Integrable Theories in any Dimension
The zero curvature representation for two dimensional integrable models is
generalized to spacetimes of dimension d+1 by the introduction of a d-form
connection. The new generalized zero curvature conditions can be used to
represent the equations of motion of some relativistic invariant field theories
of physical interest in 2+1 dimensions (BF theories, Chern-Simons, 2+1 gravity
and the CP^1 model) and 3+1 dimensions (self-dual Yang-Mills theory and the
Bogomolny equations). Our approach leads to new methods of constructing
conserved currents and solutions. In a submodel of the 2+1 dimensional CP^1
model, we explicitly construct an infinite number of previously unknown
nontrivial conserved currents. For each positive integer spin representation of
sl(2) we construct 2j+1 conserved currents leading to 2j+1 Lorentz scalar
charges.Comment: 52 pages, 4 figures, shortened version to appear in NP
Classification of integrable Weingarten surfaces possessing an sl(2)-valued zero curvature representation
In this paper we classify Weingarten surfaces integrable in the sense of
soliton theory. The criterion is that the associated Gauss equation possesses
an sl(2)-valued zero curvature representation with a nonremovable parameter.
Under certain restrictions on the jet order, the answer is given by a third
order ordinary differential equation to govern the functional dependence of the
principal curvatures. Employing the scaling and translation (offsetting)
symmetry, we give a general solution of the governing equation in terms of
elliptic integrals. We show that the instances when the elliptic integrals
degenerate to elementary functions were known to nineteenth century geometers.
Finally, we characterize the associated normal congruences
Schwarzian Derivatives and Flows of Surfaces
This paper goes some way in explaining how to construct an integrable
hierarchy of flows on the space of conformally immersed tori in n-space. These
flows have first occured in mathematical physics -- the Novikov-Veselov and
Davey-Stewartson hierarchies -- as kernel dimension preserving deformations of
the Dirac operator. Later, using spinorial representations of surfaces, the
same flows were interpreted as deformations of surfaces in 3- and 4-space
preserving the Willmore energy. This last property suggest that the correct
geometric setting for this theory is Moebius invariant surface geometry. We
develop this view point in the first part of the paper where we derive the
fundamental invariants -- the Schwarzian derivative, the Hopf differential and
a normal connection -- of a conformal immersion into n-space together with
their integrability equations. To demonstrate the effectivness of our approach
we discuss and prove a variety of old and new results from conformal surface
theory. In the the second part of the paper we derive the Novikov-Veselov and
Davey-Stewartson flows on conformally immersed tori by Moebius invariant
geometric deformations. We point out the analogy to a similar derivation of the
KdV hierarchy as flows on Schwarzian's of meromorphic functions. Special
surface classes, e.g. Willmore surfaces and isothermic surfaces, are preserved
by the flows
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