7,109 research outputs found
Brittle fracture down to femto-Joules - and below
We analyze large sets of energy-release data created by stress-induced
brittle fracture in a pure sapphire crystal at close to zero temperature where
stochastic fluctuations are minimal. The waiting-time distribution follows that
observed for fracture in rock and for earthquakes. Despite strong time
correlations of the events and the presence of large-event precursors, simple
prediction algorithms only succeed in a very weak probabilistic sense. We also
discuss prospects for further cryogenic experiments reaching close to
single-bond sensitivity and able to investigate the existence of a
transition-stress regime.Comment: REVTeX, new figure added, minor modifications to tex
Photoemission Spectra from Reduced Density Matrices: the Band Gap in Strongly Correlated Systems
We present a method for the calculation of photoemission spectra in terms of
reduced density matrices. We start from the spectral representation of the
one-body Green's function G, whose imaginary part is related to photoemission
spectra, and we introduce a frequency-dependent effective energy that accounts
for all the poles of G. Simple approximations to this effective energy give
accurate spectra in model systems in the weak as well as strong correlation
regime. In real systems reduced density matrices can be obtained from reduced
density-matrix functional theory. Here we use this approach to calculate the
photoemission spectrum of bulk NiO: our method yields a qualitatively correct
picture both in the antiferromagnetic and paramagnetic phases, contrary to
mean-field methods, in which the paramagnet is a metal
Spontaneous Conversion from Virtual to Real Photons in the Ultrastrong Coupling Regime
We show that a spontaneous release of virtual photon pairs can occur in a
quantum optical system in the ultrastrong coupling regime. In this regime,
which is attracting interest both in semiconductor and superconducting systems,
the light-matter coupling rate {\Omega}R becomes comparable to the bare
resonance frequency of photons {\omega}0. In contrast to the dynamical Casimir
effect and other pair creation mechanisms, this phenomenon does not require
external forces or time dependent parameters in the Hamiltonian.Comment: To appear on Phys. Rev. Let
On applying the set covering model to reseeding
The Functional BIST approach is a rather new BIST technique based on exploiting embedded system functionality to generate deterministic test patterns during BIST. The approach takes advantages of two well-known testing techniques, the arithmetic BIST approach and the reseeding method. The main contribution of the present paper consists in formulating the problem of an optimal reseeding computation as an instance of the set covering problem. The proposed approach guarantees high flexibility, is applicable to different functional modules, and, in general, provides a more efficient test set encoding then previous techniques. In addition, the approach shorts the computation time and allows to better exploiting the tradeoff between area overhead and global test length as well as to deal with larger circuits
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