17,728 research outputs found
Frontiers in complex dynamics
Rational maps on the Riemann sphere occupy a distinguished niche in the
general theory of smooth dynamical systems. First, rational maps are
complex-analytic, so a broad spectrum of techniques can contribute to their
study (quasiconformal mappings, potential theory, algebraic geometry, etc.).
The rational maps of a given degree form a finite-dimensional manifold, so
exploration of this {\em parameter space} is especially tractable. Finally,
some of the conjectures once proposed for {\em smooth} dynamical systems (and
now known to be false) seem to have a definite chance of holding in the arena
of rational maps.
In this article we survey a small constellation of such conjectures centering
around the density of {\em hyperbolic} rational maps --- those which are
dynamically the best behaved. We discuss some of the evidence and logic
underlying these conjectures, and sketch recent progress towards their
resolution.Comment: 18 pages. Abstract added in migration
Trees and the dynamics of polynomials
The basin of infinity of a polynomial map f : {\bf C} \arrow {\bf C}
carries a natural foliation and a flat metric with singularities, making it
into a metrized Riemann surface . As diverges in the moduli space of
polynomials, the surface collapses along its foliation to yield a
metrized simplicial tree , with limiting dynamics F : T \arrow T.
In this paper we characterize the trees that arise as limits, and show they
provide a natural boundary \PT_d compactifying the moduli space of
polynomials of degree . We show that records the limiting
behavior of multipliers at periodic points, and that any divergent meromorphic
family of polynomials \{f_t(z) : t \mem \Delta^* \} can be completed by a
unique tree at its central fiber. Finally we show that in the cubic case, the
boundary of moduli space \PT_3 is itself a tree.
The metrized trees provide a counterpart, in the setting of
iterated rational maps, to the -trees that arise as limits of
hyperbolic manifolds.Comment: 60 page
Massive quiver matrix models for massive charged particles in AdS
We present a new class of supersymmetric quiver matrix models
and argue that it describes the stringy low-energy dynamics of internally
wrapped D-branes in four-dimensional anti-de Sitter (AdS) flux
compactifications. The Lagrangians of these models differ from previously
studied quiver matrix models by the presence of mass terms, associated with the
AdS gravitational potential, as well as additional terms dictated by
supersymmetry. These give rise to dynamical phenomena typically associated with
the presence of fluxes, such as fuzzy membranes, internal cyclotron motion and
the appearance of confining strings. We also show how these models can be
obtained by dimensional reduction of four-dimensional supersymmetric quiver
gauge theories on a three-sphere.Comment: 43 pages + appendices, 4 figure
- …