Physique mathématique  matrices aléatoires et systèmes intégrables
Org:
Marco Bertola et
Dmitry Korotkin (Concordia)
[
PDF]
 MARCO BERTOLA, Concordia University
Universality in Unitary Random matrix models [PDF]

It is very well known that for Hermitean matrices the scaling limit of the eigenvalue statistics is a determinantal point field with kernel given by the sine kernel in the bulk and the Airy kernel (generally) at the edge.
We consider the normal matrix model with external field $U=Tr(M M^\dagger)  Tr( Harm(M))$ where $Harm$ stands for a (locally) harmonic function. We give a conjectural form for the strong asymptotic of the corresponding orthogonal polynomials. This form has been verified in a few outstanding cases.
We then show how to use this conjectural form to prove universality in the bulk and on the boundary of the support region for the asymptotic location of eigenvalues, where the limiting kernel are simple expressions in terms of exponentials and the complementary error function. Thus we prove universality in all cases where the conjecture has been, or will be, verified.
The proof does not require anything more than some general features.
 PAVEL BLEHER, Indiana UniversityPurdue University Indianapolis
Exact solution of the sixvertex model with DWBC. Critical line between disordered and antiferroelectric phases [PDF]

We obtain the large $N$ asymptotics of the partition function $Z_N$ of the sixvertex model with domain wall boundary conditions on the critical line between the disordered and antiferroelectric phases. Using the weights $a=1x,b=1+x,c=2,x<1$, we prove that, as $N\rightarrow\infty$, $Z_N=CF^{N^2}N^{1/12}\left(1+O(N^{1})\right)$, where $F$ is given by an explicit expression in $x$ and the $x$dependency in $C$ is determined. Our result gives a complete proof and substantially strengthens the one given in the physics literature by Bogoliubov, Kitaev and Zvonarev. Furthermore, we prove that the free energy exhibits an infinite order phase transition between the disordered and antiferroelectric phases. Our proofs are based on the large $N$ asymptotics for the underlying orthogonal polynomials which involve a nonanalytical weight function, the DeiftZhou nonlinear steepest descent method to the corresponding RiemannHilbert problem, and the Toda equation for the taufunction. This is a joint work with Thomas Bothner.
 ANTON DZHAMAY, University of Northern Colorado
Discrete Hamiltonian Structure of Schlesinger Transformations [PDF]

Schlesinger transformations are algebraic transformations of a Fuchsian system that preserve
its monodromy representation and act on the characteristic indices of the system by integral shifts. One
of the main reasons for studying these transformations is the
relationship between Schlesinger transformations and discrete Painlevé equations; this is also the main
motivation behind our work. In this talk we show how to write an elementary Schlesinger transformation
as a discrete Hamiltonian system w.r.t. the standard symplectic structure on the space of Fuchsian systems.
We also show how such transformations reduce to discrete Painlevé equations by computing two explicit
examples, d$P\big(D_{4}^{(1)}\big)$ (or difference Painlevé V) and d$P\big(A_{2}^{(1)*}\big)$. In considering
these examples we also illustrate the role played by the geometric approach to Painlevé equations not only in determining the type of the equation, but also in studying the relationship between different explicit forms of equations of the same type.
This is a joint work with Tomoyuki Takenawa (Tokyo University of Marine Science and Technology) and
Hidetaka Sakai (The University of Tokyo).
 JOHN HARNAD, Concordia University and CRM
Finite Dimensional Tau Functions [PDF]

We show how a microcosm of the $\tau$function approach to the KP hierarchy developed by the Kyoto group, consisting of solutions having a finite number of degrees of freedom, may be studied within the setting of finite dimensional Grassmannnians. This gives both a Grassmannian and fermionic interpretation of the determinantal formula of Gekhtman and Kasman, and makes evident the origin of the "rank$1$'' condition characterizing finite dimensional reductions. In particular, this includes the wellknown cases of polynomial $\tau$functions, those associated to CalogeroMoser pole dynamics, multisolitions and their degenerations. It also sheds light on the recently introduced notion of "convolution flows". (Based on joint work with F. Balogh and T. Dinis da Fonseca)
 DMITRY KOROTKIN, Concordia University
BakerAkhiezer spinor and Bergman taufunction on moduli spaces of meromorphic differentials [PDF]

We derive variational formulas of RauchAhlfors type on moduli spaces of meromorphic differentials
on Riemann surfaces. In particular, we show that the derivatives of the Szeg\"o kernel with respect to homological coordinates on these spaces are expressed via Hirota derivative of that kernel.
This formula is used to derive variational formulas for the BakerAkhiezer kernel,
which in particular encode the KPtype hierarchies, as well as dependence of the bakerAkhiezer kernel on the moduli of the Riemann surface.
We also define Bergman taufunction on these spaces, compute it in several important special cases
and describe it as a section of an appropriate line bundle; this allows to express the Hodge class on these moduli spaces in terms of the tautological class.
 ANDREW MCINTIRE, Bennington College
Chernsimons invariant of infinite volume hyperbolic 3manifolds [PDF]

We define a ChernSimons invariant for a certain class of infinite volume hyperbolic 3manifolds. We then prove an expression relating the Bergman tau function on a cover of the Hurwitz space, to the lifting of the function $F$ defined by Zograf on Teichm\"uller space, and another holomorphic function on the cover of the Hurwitz space which we introduce. If the point in cover of the Hurwitz space corresponds to a Riemann surface $X$, then this function is constructed from the renormalized volume and our ChernSimons invariant for the bounding 3manifold of $X$ given by Schottky uniformization, together with a regularized Polyakov integral relating determinants of Laplacians on $X$ in the hyperbolic and singular flat metrics. Combining this with a result of Kokotov and Korotkin, we obtain a similar expression for the isomonodromic tau function of Dubrovin. We also obtain a relation between the ChernSimons invariant and the eta invariant of the bounding 3manifold, with defect given by the phase of the Bergman tau function of $X$.
 ANTHONY METCALFE, KTH, Royal Institute of Technology, Sweden
Universality classes of lozenge tilings of a polyhedron [PDF]

A regular hexagon can be tiled with lozenges of three different orientations. Letting the hexagon have sides of length $n$, and the lozenges have sides of length $1$, we can consider the asymptotic behaviour of a typical tiling as $n$ increases. Typically, near the corners of the hexagon there are regions of "frozen" tiles, and there is a "disordered" region in the center which is approximately circular.
More generally one can consider lozenge tilings of polyhedra with more complex boundary conditions. The local asymptotic behaviour of tiles near the boundary of the equivalent "frozen" and "disordered" regions is of particular interest. In this talk, we shall discuss work in progress in which we classify necessary conditions under which such tiles behave asymptotically like a determinantal random point field with the Airy kernel, and also with the Pearcey kernel. We do this by considering an equivalent interlaced discrete particle system.
 CHRISTOPHER SINCLAIR, University of Oregon
Kernel Asymptotics for the Mahler Ensemble of Real Polynomials [PDF]

The Mahler measure of a polynomial is the absolute value of the lead coefficient times the product of the absolute values of the roots outside the unit circle. The set of degree $N$ polynomials with Mahler measure at most 1 forms a bounded subset of $\mathbb{R}^{N+1}$. The roots of polynomials chosen uniformly from this region yields a Pfaffian point process on the complex plane similar to that of Ginibre's real ensemble but with a different (subexponential) weight. The limiting density of roots is uniform measure on the unit circle, and we discuss the scaling limits for the matrix kernel in a neighborhood of a point on the unit circle. New phenomena appear in a neighborhood of 1, since the spectrum consists of both real roots and complex conjugate pairs. Relationships with the related determinantal ensemble (of roots of complex polynomials) will be discussed as well as an electrostatic and matrix model for the ensemble.
 JACEK SZMIGIELSKI, University of Saskatchewan
Two applications of Cauchy biorthogonal polynomials [PDF]

Cauchy biorthogonal polynomials were introduced by M. Bertola, M. Gekhtman and the speaker. They appeared originally in the
computations of peakon solutions to the DegasperisProcessi equation. In this talk I will review basic properties of this class of
polynomials and describe the highlights of two recent applications; one, to the solution of certain inverse problem associated to a system of equations put forward by Geng and Xue, the other, to the computation of the correlation kernels for the Cauchy twomatrix model with Laguerre type onebody interactions.
 BALINT VIRAG, University of Toronto
Random operators at the edge [PDF]

The density of states of a random GUE matrix at the edge behaves like $x^{1/2}$. The large$n$ limit of this matrix is the Stochastic Airy Operator, whose ground state has TracyWidom distribution. The Painleve II formulas for this distribution can be derived using the random operator.
The density of states of some natural classes of matrix models have different power law at the edge. I will describe the conjectured limiting operators and state some open problems about their behavior.
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