51 research outputs found
Nonequilibrium properties of an atomic quantum dot coupled to a Bose-Einstein condensate
We study nonequilibrium properties of an atomic quantum dot (AQD) coupled to
a Bose-Einstein condensate (BEC) within Keldysh-Green's function formalism when
the AQD level is varied harmonically in time. Nonequilibrium features in the
AQD energy absorption spectrum are the side peaks that develop as an effect of
photon absorption and emission. We show that atoms can be efficiently
transferred from the BEC into the AQD for the parameter regime of current
experiments with cold atoms.Comment: 8 pages, 2 figures, to appear in the special issue "Novel Quantum
Phases and Mesoscopic Physics in Quantum Gases" of The European Physical
Journal - Special Topic
Stiffness constants prediction of nanocomposites using a periodic 3D-FEM model
Predictive models, which enable the prediction of nanocomposite properties from their morphologies and account for polymer orientation, could greatly assist the exploitation of this new class of materials in more diversified and demanding market fields. This article focuses on the prediction of effective elastic properties (Young's moduli) of polymer nanocomposite films (copolyamide-6/nanoclay) using 3D analytical (based on the Mori-Tanaka theory) and 3D finite element (FE) models. The analytical model accounts for the orientation of polymer chains induced by drawing. 3D FE model exploits the representative volume element concept and accounts for the nanocomposite morphology as determined from transmission electron microscopy experiments. Model predictions were compared with experimental results obtained for nanocomposite films produced by means a pilot-scale film blowing equipment and collected at different draw ratios
Topological order in Josephson junction ladders with Mobius boundary conditions
We propose a CFT description for a closed one-dimensional fully frustrated
ladder of quantum Josephson junctions with Mobius boundary conditions, in
particular we show how such a system can develop topological order. Such a
property is crucial for its implementation as a "protected" solid state qubit.Comment: 14 pages, 3 figures, to appear in JSTA
Functionalization of graphene related materials with biosourced C-3 and C-6 building blocks. From synthesis to applications
The functionalization of sp2 carbon allotropes is one of the hot research topics in advanced research
on materials. Nowadays, carbon nanotubes and graphene related materials are extensively studied
due to their exceptional mechanical and electrical properties. They are capable of substantially
improving the properties of polymeric materials. Their functionalization is a crucial step, for allowing
an even dispersion in the matrix.
In this research, the functionalization of graphene related materials was performed with biosourced
C-3 and C-6 molecules. They were glycerol and galactaric acid derivatives: pyrrole
compounds (PyC) and 2-pyrones. The reactions for their synthesis and for the carbon
allotrope functionalization were green and characterized by high atom efficiency, with a yield up to
96%. Indeed, the reactions were carried out in the absence of solvents and catalysts and adducts were
obtained by simply mixing, with the help of either thermal or mechanical energy. The developed
functionalization methods were successful for: carbon black, carbon nanotubes, few layers graphene.
The bulk structure of the carbon substrate was left substantially unaltered: functionalization occurred
in peripheral positions, at the edges of the graphene layers. Functional groups of defined chemical
structure were covalently bound to the carbon material and stable adducts, up to very high
temperature, were formed. Reliable hypotheses for the functionalization mechanisms were
elaborated. In Figure 1b the supposed domino reaction based on the pyrrole compound, with the Diels
Alder cycloaddition as the last step is represented.
Such functionalization technique was developed as a pervasive technology, which allowed to pursue
a variety of applications: (i) decoration with metals to obtain catalysts for the selective deuteration of
pharmaceutical molecules as well as antibacterial ingredients (ii) rubber compounds for
dynamic-mechanical applications (tires) (iii) conductive inks
Twisted CFT and bilayer Quantum Hall systems
We identify the impurity interactions of the recently proposed CFT
description of a bilayer Quantum Hall system at filling nu =m/(pm+2) in Mod.
Phys. Lett. A 15 (2000) 1679. Such a CFT is obtained by m-reduction on the one
layer system, with a resulting pairing symmetry and presence of quasi-holes.
For the m=2 case boundary terms are shown to describe an impurity interaction
which allows for a localized tunnel of the Kondo problem type. The presence of
an anomalous fixed point is evidenced at finite coupling which is unstable with
respect to unbalance and flows to a vacuum state with no quasi-holes.Comment: 15 pages, 1 figure, Late
Fully frustrated Josephson junction ladders with Mobius boundary conditions as topologically protected qubits
We show how to realize a ``protected'' qubit by using a fully frustrated
Josephson Junction ladder (JJL) with Mobius boundary conditions. Such a system
has been recently studied within a twisted conformal field theory (CFT)
approach (Mod. Phys. Lett. A 15 (2000) 1679; Nucl. Phys. B 641 (2002) 547) and
shown to develop the phenomenon of flux fractionalization (Eur. Phys. J. B 49
(2006) 83). The relevance of a ``closed'' geometry has been fully exploited in
relating the topological properties of the ground state of the system to the
presence of half flux quanta and the emergence of a topological order has been
predicted (JSTAT (2005) P03006). In this letter the stability and
transformation properties of the ground states under adiabatic magnetic flux
change are analyzed and the deep consequences on the realization of a solid
state qubit, protected from decoherence, are presented.Comment: 21 pages, 2 figures, in print in Phys. Lett.
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