57 research outputs found
Moments of the Wigner delay times
The Wigner time delay is a measure of the time spent by a particle inside the
scattering region of an open system. For chaotic systems, the statistics of the
individual delay times (whose average is the Wigner time delay) are thought to
be well described by random matrix theory. Here we present a semiclassical
derivation showing the validity of random matrix results. In order to simplify
the semiclassical treatment, we express the moments of the delay times in terms
of correlation functions of scattering matrices at different energies. In the
semiclassical approximation, the elements of the scattering matrix are given in
terms of the classical scattering trajectories, requiring one to study
correlations between sets of such trajectories. We describe the structure of
correlated sets of trajectories and formulate the rules for their evaluation to
the leading order in inverse channel number. This allows us to derive a
polynomial equation satisfied by the generating function of the moments. Along
with showing the agreement of our semiclassical results with the moments
predicted by random matrix theory, we infer that the scattering matrix is
unitary to all orders in the semiclassical approximation.Comment: Refereed version. 18 pages, 5 figure
Multiplicity of periodic solutions in bistable equations
We study the number of periodic solutions in two first order non-autonomous
differential equations both of which have been used to describe, among other
things, the mean magnetization of an Ising magnet in the time-varying external
magnetic field. When the strength of the external field is varied, the set of
periodic solutions undergoes a bifurcation in both equations. We prove that
despite profound similarities between the equations, the character of the
bifurcation can be very different. This results in a different number of
coexisting stable periodic solutions in the vicinity of the bifurcation. As a
consequence, in one of the models, the Suzuki-Kubo equation, one can effect a
discontinuous change in magnetization by adiabatically varying the strength of
the magnetic field.Comment: Fixed typos; added and reordered figures. 18 pages, 6 figures. An
animation of orbits is available at
http://www.maths.strath.ac.uk/~aas02101/bistable
Universality of the momentum band density of periodic networks
The momentum spectrum of a periodic network (quantum graph) has a band-gap
structure. We investigate the relative density of the bands or, equivalently,
the probability that a randomly chosen momentum belongs to the spectrum of the
periodic network. We show that this probability exhibits universal properties.
More precisely, the probability to be in the spectrum does not depend on the
edge lengths (as long as they are generic) and is also invariant within some
classes of graph topologies
Dependence of the spectrum of a quantum graph on vertex conditions and edge lengths
We study the dependence of the quantum graph Hamiltonian, its resolvent, and
its spectrum on the vertex conditions and graph edge lengths. In particular,
several results on the interlacing (bracketing) of the spectra of graphs with
different vertex conditions are obtained and their applications are discussed.Comment: 19 pages, 1 figur
- ā¦