4,385 research outputs found
Why Study Noise due to Two Level Systems: A Suggestion for Experimentalists
Noise is often considered to be a nuisance. Here we argue that it can be a
useful probe of fluctuating two level systems in glasses. It can be used to:
(1) shed light on whether the fluctuations are correlated or independent
events; (2) determine if there is a low temperature glass or phase transition
among interacting two level systems, and if the hierarchical or droplet model
can be used to describe the glassy phase; and (3) find the lower bound of the
two level system relaxation rate without going to ultralow temperatures.
Finally we point out that understanding noise due to two level systems is
important for technological applications such as quantum qubits that use
Josephson junctions.Comment: 15 pages, 4 figures, Latex, to be published in J. Low Temp. Phys.
issue in honor of S. Hunklinge
Numerical Verification of the Weak Turbulent Model for Swell Evolution
The purpose of this article is numerical verification of the theory of weak
turbulence. We performed numerical simulation of an ensemble of nonlinearly
interacting free gravity waves (swell) by two different methods: solution of
primordial dynamical equations describing potential flow of the ideal fluid
with a free surface and, solution of the kinetic Hasselmann equation,
describing the wave ensemble in the framework of the theory of weak turbulence.
In both cases we observed effects predicted by this theory: frequency
downshift, angular spreading and formation of Zakharov-Filonenko spectrum
. To achieve quantitative coincidence of the
results obtained by different methods, one has to supply the Hasselmann kinetic
equation by an empirical dissipation term modeling the coherent
effects of white-capping. Using of the standard dissipation terms from
operational wave predicting model ({\it WAM}) leads to significant improvement
on short times, but not resolve the discrepancy completely, leaving the
question about optimal choice of open. In a long run {\it WAM}
dissipative terms overestimate dissipation essentially.Comment: 41 pages, 37 figures, 1 table. Submitted in European Journal of
Mechanics B/Fluid
Free expansion of impenetrable bosons on one-dimensional optical lattices
We review recent exact results for the free expansion of impenetrable bosons
on one-dimensional lattices, after switching off a confining potential. When
the system is initially in a superfluid state, far from the regime in which the
Mott-insulator appears in the middle of the trap, the momentum distribution of
the expanding bosons rapidly approaches the momentum distribution of
noninteracting fermions. Remarkably, no loss in coherence is observed in the
system as reflected by a large occupation of the lowest eigenstate of the
one-particle density matrix. In the opposite limit, when the initial system is
a pure Mott insulator with one particle per lattice site, the expansion leads
to the emergence of quasicondensates at finite momentum. In this case,
one-particle correlations like the ones shown to be universal in the
equilibrium case develop in the system. We show that the out-of-equilibrium
behavior of the Shannon information entropy in momentum space, and its contrast
with the one of noninteracting fermions, allows to differentiate the two
different regimes of interest. It also helps in understanding the crossover
between them.Comment: 21 pages, 14 figures, invited brief revie
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