284 research outputs found
The Andreev states of a superconducting quantum dot: mean field vs exact numerical results
We analyze the spectral density of a single level quantum dot coupled to
superconducting leads focusing on the Andreev states appearing within the
superconducting gap. We use two complementary approaches: the numerical
renormalization group and the Hartree-Fock approximation. Our results show the
existence of up to four bound states within the gap when the ground state is a
spin doublet (\pi\ phase). Furthermore the results demonstrate the reliability
of the mean field description within this phase. This is understood from a
complete correspondence that can be established between the exact and the mean
field quasiparticle excitation spectrumComment: 6 pages, 5 figure
Non-equilibrium dynamics of Andreev states in the Kondo regime
The transport properties of a quantum dot coupled to superconducting leads
are analyzed. It is shown that the quasiparticle current in the Kondo regime is
determined by the non-equilibrium dynamics of subgap states (Andreev states)
under an applied voltage. The current at low bias is suppressed exponentially
for decreasing Kondo temperature in agreement with recent experiments. We also
predict novel interference effects due to multiple Landau-Zener transitions
between Andreev states.Comment: Revtex4, 4 pages, 4 figure
Microscopic theory of the proximity effect in superconductor-graphene nanostructures
We present a theoretical analysis of the proximity effect at a
graphene-superconductor interface. We use a tight-binding model for the
electronic states in this system which allows to describe the interface at the
microscopic level. Two different interface models are proposed: one in which
the superconductor induces a finite pairing in the graphene regions underneath,
thus maintaining the honeycomb structure at the interface and one that assumes
that the graphene layer is directly coupled to a bulk superconducting
electrode. We show that properties like the Andreev reflection probability and
its channel decomposition depend critically on the model used to describe the
interface. We also study the proximity effect on the local density of states on
the graphene. For finite layers we analyze the induced minigap and how it is
reduced when the length of the layer increases. Results for the local density
of states profiles for finite and semi-infinite layers are presented.Comment: 9 pages, 7 figures, submitted to Phys. Rev.
Dressed tunneling approximation for electronic transport through molecular transistors
A theoretical approach for the non-equilibrium transport properties of
nanoscale systems coupled to metallic electrodes with strong electron-phonon
interactions is presented. It consists in a resummation of the dominant Feynman
diagrams from the perturbative expansion in the coupling to the leads. We show
that this scheme eliminates the main pathologies found in previous simple
analytical approaches for the polaronic regime. The results for the spectral
and transport properties are compared with those from several other approaches
for a wide range of parameters. The method can be formulated in a simple way to
obtain the full counting statistics. Results for the shot and thermal noise are
presented.Comment: 11 pages, 11 figures. Accepted for publication in Physical Review
La expresividad en los informativos radiofónicos
La expresividad es una cualidad ligada a la eficacia comunicativa que podemos cultivar en la radio construyendo mensajes más atractivos para los oyentes. Por eso, este trabajo tiene como objetivo determinar el grado de expresividad en los informativos de las cadenas nacionales españolas considerando variables como la correcta utilización y combinación de los elementos del lenguaje radiofónico y la elección de los géneros informativos. La principal conclusión del estudio es que en los programas de noticias no se emplean todos los recursos de expresividad que brinda el medio radiofónico para conquistar la atención de la audiencia
Resonant tunneling through a small quantum dot coupled to superconducting leads
We address the problem of non-linear transport through discrete electronic
levels in a small quantum dot coupled to superconducting electrodes. In our
approach the low temperature I-V characteristics can be calculated including
all multiple quasi-particle and Andreev processes. The limit of very weak
coupling to the leads and large charging energies is briefly analyzed comparing
the calculated lineshapes of the I-V curves with recent experimental results.
When the coupling to the leads increases and Coulomb blockade effects can be
neglected, the combination of multiple Andreev processes and resonant
transmission gives rise to a rich subgap structure which largely differs from
the one found in the more studied S-N-S systems. We show how multiple processes
can be included within a simple sequential tunneling picture qualitatively
explaining the subgap structure. We suggest an experimental set-up where the
predicted effects could be observed.Comment: 11 pages, 4 postscript figures, to be published in Phys. Rev. B
(rapid communications
Reseña de libro: Revistas científicas: Situación actual y retos de futuro
Ficha editorialTítulo: Revistas científicas: Situación actual y retos de futuroEditor: Ernest AbadalEditorial: Edicions de la Universitat de BarcelonaNúmero de páginas: 276ISBN: 978-84-9168-004-8Copyright © Edicions de la Universitat de BarcelonaEste documento está sujeto a la licencia de Reconocimiento-NoComercial-SinObraDerivada de Creative CommonsFicha editorialTítulo: Revistas científicas: Situación actual y retos de futuroEditor: Ernest AbadalEditorial: Edicions de la Universitat de BarcelonaNúmero de páginas: 276ISBN: 978-84-9168-004-8Copyright © Edicions de la Universitat de BarcelonaEste documento está sujeto a la licencia de Reconocimiento-NoComercial-SinObraDerivada de Creative Common
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