69 research outputs found
Graph-like asymptotics for the Dirichlet Laplacian in connected tubular domains
We consider the Dirichlet Laplacian in a waveguide of uniform width and
infinite length which is ideally divided into three parts: a "vertex region",
compactly supported and with non zero curvature, and two "edge regions" which
are semi-infinite straight strips. We make the waveguide collapse onto a graph
by squeezing the edge regions to half-lines and the vertex region to a point.
In a setting in which the ratio between the width of the waveguide and the
longitudinal extension of the vertex region goes to zero, we prove the
convergence of the operator to a selfadjoint realization of the Laplacian on a
two edged graph. In the limit operator, the boundary conditions in the vertex
depend on the spectral properties of an effective one dimensional Hamiltonian
associated to the vertex region.Comment: Major revision. Reviewed introduction. Changes in Th. 1, Th. 2, and
Th. 3. Updated references. 23 page
Nontrivial edge coupling from a Dirichlet network squeezing: the case of a bent waveguide
In distinction to the Neumann case the squeezing limit of a Dirichlet network
leads in the threshold region generically to a quantum graph with disconnected
edges, exceptions may come from threshold resonances. Our main point in this
paper is to show that modifying locally the geometry we can achieve in the
limit a nontrivial coupling between the edges including, in particular, the
class of -type boundary conditions. We work out an illustration of this
claim in the simplest case when a bent waveguide is squeezed.Comment: LaTeX, 16 page
Relative partition function of Coulomb plus delta interaction
The relative partition function and the relative zeta function of the
perturbation of the Laplace operator by a Coulomb potential plus a point
interaction centered in the origin is discussed. Applications to the study of
the Casimir effect are indicated.Comment: Minor misprints corrected. 24 page
Time dependent delta-prime interactions in dimension one
We solve the Cauchy problem for the Schr\"odinger equation corresponding to
the family of Hamiltonians in which
describes a -interaction with time-dependent strength .
We prove that the strong solution of such a Cauchy problem exits whenever the
map belongs to the fractional Sobolev space
, thus weakening the hypotheses which would be required by
the known general abstract results. The solution is expressed in terms of the
free evolution and the solution of a Volterra integral equation.Comment: minor changes, 10 page
Effective equation for a system of mechanical oscillators in an acoustic field
We consider a one dimensional evolution problem modeling the dynamics of an
acoustic field coupled with a set of mechanical oscillators. We analyze
solutions of the system of ordinary and partial differential equations with
time-dependent boundary conditions describing the evolution in the limit of a
continuous distribution of oscillators.Comment: Improved Theorem 2. Updated introduction and references. Added 1
figure. 11 page
Bounds for the Stieltjes Transform and the Density of States of Wigner Matrices
We consider ensembles of Wigner matrices, whose entries are (up to the
symmetry constraints) independent and identically distributed random variables.
We show the convergence of the Stieltjes transform towards the Stieltjes
transform of the semicircle law on optimal scales and with the optimal rate.
Our bounds improve previous results, in particular from [22,10], by removing
the logarithmic corrections. As applications, we establish the convergence of
the eigenvalue counting functions with the rate and the rigidity
of the eigenvalues of Wigner matrices on the same scale. These bounds improve
the results of [22,10,23].Comment: New title, former title "Optimal Bounds on the Stieltjes Transform of
Wigner Matrices". Updated reference
On the structure of critical energy levels for the cubic focusing NLS on star graphs
We provide information on a non trivial structure of phase space of the cubic
NLS on a three-edge star graph. We prove that, contrarily to the case of the
standard NLS on the line, the energy associated to the cubic focusing
Schr\"odinger equation on the three-edge star graph with a free (Kirchhoff)
vertex does not attain a minimum value on any sphere of constant -norm. We
moreover show that the only stationary state with prescribed L^2-norm is indeed
a saddle point
Stable standing waves for a NLS on star graphs as local minimizers of the constrained energy
On a star graph made of halflines (edges) we consider a
Schr\"odinger equation with a subcritical power-type nonlinearity and an
attractive delta interaction located at the vertex. From previous works it is
known that there exists a family of standing waves, symmetric with respect to
the exchange of edges, that can be parametrized by the mass (or -norm) of
its elements. Furthermore, if the mass is small enough, then the corresponding
symmetric standing wave is a ground state and, consequently, it is orbitally
stable. On the other hand, if the mass is above a threshold value, then the
system has no ground state. Here we prove that orbital stability holds for
every value of the mass, even if the corresponding symmetric standing wave is
not a ground state, since it is anyway a {\em local} minimizer of the energy
among functions with the same mass. The proof is based on a new technique that
allows to restrict the analysis to functions made of pieces of soliton,
reducing the problem to a finite-dimensional one. In such a way, we do not need
to use direct methods of Calculus of Variations, nor linearization procedures.Comment: 18 pages, 2 figure
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