15 research outputs found
Survival probability (heat content) and the lowest eigenvalue of Dirichlet Laplacian
We study the survival probability of a particle diffusing in a
two-dimensional domain, bounded by a smooth absorbing boundary. The short-time
expansion of this quantity depends on the geometric characteristics of the
boundary, whilst its long-time asymptotics is governed by the lowest eigenvalue
of the Dirichlet Laplacian defined on the domain. We present a simple algorithm
for calculation of the short-time expansion for an arbitrary "star-shaped"
domain. The coefficients are expressed in terms of powers of boundary
curvature, integrated around the circumference of the domain. Based on this
expansion, we look for a Pad\'e interpolation between the short-time and the
long-time behavior of the survival probability, i.e. between geometric
characteristics of the boundary and the lowest eigenvalue of the Dirichlet
Laplacian.Comment: Accepted in IJMP
Universal conductance fluctuations in non-integer dimensions
We propose an Ansatz for Universal conductance fluctuations in continuous
dimensions from 0 up to 4. The Ansatz agrees with known formulas for integer
dimensions 1, 2 and 3, both for hard wall and periodic boundary conditions. The
method is based solely on the knowledge of energy spectrum and standard
assumptions. We also study numerically the conductance fluctuations in 4D
Anderson model, depending on system size L and disorder W. We find a small
plateau with a value diverging logarithmically with increasing L. Universality
gets lost just in 4D.Comment: 4 pages, 4 figures submitted to Phys. Rev.
Further analysis of the connected moments expansion
We apply the connected moments expansion to simple quantum--mechanical
examples and show that under some conditions the main equations of the approach
are no longer valid. In particular we consider two--level systems, the harmonic
oscillator and the pure quartic oscillator.Comment: 19 pages; 2 tables; 4 figure
Exact Solvability of the two-photon Rabi Hamiltonian
Exact spectrum of the two-photon Rabi Hamiltonian is found, proceeding in
full analogy with the solution of standard (one-photon) Rabi Hamiltonian,
published by Braak in Phys. Rev. Lett. 107, 100401 (2011). The Hamiltonian is
rewritten as a set of two differential equations. Symmetries that get hidden
after further treatment are found. One can plainly see, how the Hilbert space
splits into four disjunct subspaces, categorized by four values of the symmetry
parameter . There were only two values for the standard
Rabi model. Four analytic functions are introduced by a recurrence scheme for
the coefficients of their series expansion. All their roots yield the complete
spectrum of the Hamiltonian. Eigenstates in Bargmann space are also at
disposal
Universality of the critical conductance distribution in various dimensions
We study numerically the metal - insulator transition in the Anderson model
on various lattices with dimension (bifractals and Euclidian
lattices). The critical exponent and the critical conductance
distribution are calculated. We confirm that depends only on the {\it
spectral} dimension. The other parameters - critical disorder, critical
conductance distribution and conductance cummulants - depend also on lattice
topology. Thus only qualitative comparison with theoretical formulae for
dimension dependence of the cummulants is possible
