Analysis on Singular Manifolds
Org:
Alexey Kokotov (Concordia) and
Frédéric Rochon (UQAM)
[
PDF]
 YANNICK BONTHONNEAU, CIRGET  CRM
Continuous and discrete Weyl laws for negatively curved cusp manifolds [PDF]

The purpose of my talk will be to give a new refinement in the spectral theory of the Laplace operator on manifolds with exact hyperbolic cusps, when the curvature is negative. I will give estimates on some spectral counting functions.
The usual counting function for the point spectrum $N(T)$ is not the relevant quantity as the Laplace operator has continuous spectrum. Instead, we have to consider $N(T) + S(T)$, where $S(T)$ is the phase shift in the appropriate scattering problem. First, when the curvature is negative, we will see that
\[
N(T) + S(T) = \frac{\mathrm{vol}(B^\ast M)}{(2\pi)^{n}} T^n + aT \log T + bT^{n1} + \mathcal{O}\left(\frac{T^{n1}}{\log T} \right)
\]
with some constants $a$ and $b$.
The function $z \mapsto \exp i S(i((n1)/2 z))$ has a meromorphic extension to $\mathbb{C}$, with its poles contained in $\Re z < (n1)/2$. These poles can be seen as a discrete spectral set replacing the eigenvalues in the compact case, they are called resonances. I proved that for a generic set of metrics, most of these resonances are contained in a strip $\{\delta < \Re z < (n1)/2\}$ at high frequency, where $\delta < (n1)/2$. Under this genericity assumption, we will see that
\[
\#\{ s \text{ resonance }\ \Re s > \delta,\ \Im s \leq T \} = A T^n + B T^{n1} + C T \log T + \mathcal{O}\left( \frac{T^{n1}}{\log T} \right).
\]
 DMITRY JAKOBSON, McGill
Gaussian measures on manifolds of metrics [PDF]

This is joint work with Y. Canzani, B. Clarke, N. Kamran, L. Silberman and J. Taylor. We define Gaussian measures on manifolds of metrics with the fixed volume form. We next compute the moment generating function for the L2 (Ebin) distance to the reference metric. We also prove integrability results (with respect to our measures) for functionals such as Laplace eigenvalues, diameter, and volume entropy.
 VICTOR KALVIN, Concordia University
Moduli spaces of meromorphic functions and determinant of Laplacian [PDF]

The Hurwitz space is the moduli space of pairs $(X,f)$, where $X$ is a compact Riemann surface and f is a meromorphic function on X. We consider the Laplace operator on the flat noncompact singular Riemannian manifold $(X, df^2)$. We define a regularized relative determinant of the Laplace operator and obtain an explicit expression for the determinant in terms of the basic objects on the underlying Riemann surface (the prime form, thetafunctions, the canonical meromorphic bidifferential) and the divisor of the meromorphic differential $df$. A surgery formula of the type of BurgheleaFriedlanderKappeler (for the relative determinant of the Laplace operator on singular flat surfaces with conical and Euclidean ends) allows to close the conical/Euclidean ends and thus reduces the proof of explicit expression for the relative determinant to the proof of a similar expression for the zetaregularized determinant of Laplace operator on the (compact) manifold with closed ends. The talk is based on a joint work with Alexey Kokotov and Luc Hillairet.
 SPIRO KARIGIANNIS, University of Waterloo
Existence of $G_2$ conifolds: a progress report [PDF]

Compact $G_2$ manifolds with isolated conical singularities, also called $G_2$ conifolds, are important objects in physics. They are expected to exist in abundance but no examples have yet been found. I will review past work of myself (on desingularization) and myself with Jason Lotay (on deformation theory) that gives strong mathematical evidence for their existence. Then I will discuss our current progress (with Lotay) on a possible construction of $G_2$ conifolds, by generalizing a new construction of myself and Dominic Joyce of smooth compact $G_2$ manifolds.
 CHRIS KOTTKE, Northeastern University
Partial compactification and metric asymptotics of monopoles [PDF]

I will describe a partial compactification of the moduli
space, $M_k$, of $\mathrm {SU}(2)$ magnetic monopoles on ${\mathbb R}^3$, wherein monopoles of
charge $k$ decompose into widely separated `monopole clusters' of lower
charge going off to infinity at comparable rates. The hyperkahler metric
on $M_k$ has a complete asymptotic expansion, the leading terms of which
generalize the asymptotic metric discovered by Bielawski, Gibbons and
Manton in the case that the monopoles are all widely separated. This is
joint work with M. Singer, and is part of a larger work in progress with
R. Melrose and K. Fritzsch to fully compactify the $M_k$ as manifolds with
corners and compute their $L^2$ cohomology.
 THOMAS KRAINER, Penn State Altoona
Boundary Value Problems for Elliptic Wedge Operators of First Order [PDF]

Spaces with singularities of edge type are modeled by a smooth compact manifold with boundary, where the boundary is the total space of a locally trivial fibration. The relation with the singular space is given by collapsing the fibers to points. On such manifolds there is a natural class of incomplete Riemannian metrics (incompleteedge metrics) that reflect the conic degeneration of the fibers at the boundary. Geometric operators associated with such metrics are examples for the broader class of wedge differential operators. In the case of the trivial boundary fibration (fiber is a point), incompleteedge metrics are precisely the smooth metrics up to the boundary, and the class of wedge differential operators includes all regular differential operators with smooth coefficients up to the boundary.
In this talk, I will report about joint work with Gerardo Mendoza addressing the problem of wellposedness of elliptic equations for wedge operators of first order. Central to the investigation is the development of an appropriate notion of boundary condition associated with the singular locus (i.e. the edge). In the case of the trivial boundary fibration, our theory includes the classical theory of elliptic boundary problems for firstorder operators as a special case.
 GERARDO MENDOZA, Temple University
Spectral instability of selfadjoint extensions of symmetric elliptic cone operators [PDF]

Let $A:C_c^\infty(\dot{M};E)\subset x^{\nu/2}L^2_b(\dot{M};E)\to x^{\nu/2}L^2_b(\smash[t]{\dot{M}};F)$ be an elliptic cone operator acting on sections of a vector bundle $E$ over a smooth compact manifold $M$ with boundary $\partial M=\{x=0\}$. Suppose $A$ is symmetric, bounded from below, and admits more than one selfadjoint extension. The family, $\mathfrak{SA}$, of domains of such extensions is a smooth compact realanalytic manifold. The spectrum of $A$ with any domain $D\in \mathfrak{SA}$ is bounded below, but there exist domains $D_0$ which admit a neighborhood $U\subset \mathfrak{SA}$ for which the property $\forall \zeta\in \mathbb R$ $\exists D\in U$ s.t. $\inf\mathrm{spec}(A_D)<\zeta$ holds. The set of such domains is a codimension $1$ (real)analytic variety in $\mathfrak{SA}$ which will be described explicitly.
 ERIC WOOLGAR, University of Alberta
APEs [PDF]

I will discuss asymptotically hyperbolic manifolds and subtypes, especially Asymptotically Poincar\'eEinstein (APE) manifolds. These are manifolds whose metrics admit a FeffermanGraham type expansion near conformal infinity, such that the first few leading terms are determined by the Einstein equations. APEs appear in physics, both as time slices of asymptotically Antide Sitter (AdS) spacetimes and as Wick rotations of static AdS spacetimes. Among the invariants that can (sometimes) be associated to APEs are mass and renormalized volume. For APEs that represent static AdS black holes in 4 dimensions, the renormalized volume and the mass of a static slice can be related. Remarkably, this relationship, which can be established purely on geometric grounds, is the Gibbs relation of black hole thermodynamics. A related result is that APEs which are timesymmetric slices of globally static AdS spacetimes cannot have positive mass. Examples are provided by HorowitzMyers geons, which are complete APEs with scalar curvature $S=n(n1)$ and negative mass. They serve as timesymmetric slices of socalled AdS solitons, which are Einstein spacetimes with toroidal conformal infinity. The HorowitzMyers "positive" energy conjecture proposes that HorowitzMyers geons minimize the mass over all APEs with scalar curvature $S\ge n(n1)$ and the same toroidal conformal infinity. The conjecture is a major open problem in the field, but it is possible to show that if this conjecture is true then there is a rigidity theorem for HorowitzMyers geons: the leastmass geon is the unique complete APE having that mass and obeying $S\ge n(n1)$.
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