4,419 research outputs found
Optimized Effective Potential for Quantum Electrodynamical Time-Dependent Density Functional Theory
We propose a practical approximation to the exchange-correlation functional
of (time-dependent) density functional theory for many-electron systems coupled
to photons. The (time non-local) optimized effective potential (OEP) equation
for the electron- photon system is derived. We test the new approximation in
the Rabi model from weak to strong coupling regimes. It is shown that the OEP
(i) improves the classical description, (ii) reproduces the quantitative
behavior of the exact ground-state properties and (iii) accurately captures the
dynamics entering the ultra-strong coupling regime. The present formalism opens
the path to a first-principles description of correlated electron-photon
systems, bridging the gap between electronic structure methods and quantum
optics for real material applications.Comment: 5 pages, 2 figure
Photocurrent-based detection of Terahertz radiation in graphene
Graphene is a promising candidate for the development of detectors of
Terahertz (THz) radiation. A well-known detection scheme due to Dyakonov and
Shur exploits the confinement of plasma waves in a field-effect transistor
(FET), whereby a dc photovoltage is generated in response to a THz field. This
scheme has already been experimentally studied in a graphene FET [L. Vicarelli
et al., Nature Mat. 11, 865 (2012)]. In the quest for devices with a better
signal-to-noise ratio, we theoretically investigate a plasma-wave photodetector
in which a dc photocurrent is generated in a graphene FET. The rectified
current features a peculiar change of sign when the frequency of the incoming
radiation matches an even multiple of the fundamental frequency of plasma waves
in the FET channel. The noise equivalent power per unit bandwidth of our device
is shown to be much smaller than that of a Dyakonov-Shur detector in a wide
spectral range.Comment: 5 pages, 4 figure
Strangeness Production in pp,pA,AA Interactions at SPS Energies.HIJING Approach
In this report we have made a systematic study of strangeness production in
proton-proton(pp),proton-nucleus(pA) and nucleus- nucleus(AA) collisions at
CERN Super Proton Synchroton energies, using \\ (version ). Numerical results for mean
multiplicities of neutral strange particles ,as well as their ratios to
negatives hadrons() for
p-p,nucleon-nucleon(N-N),\,\,p-S,\,\,p-Ag,\,\,p-Au('min. bias')collisions and
p-Au,\,\,S-S,\,\,S-Ag,\,\,S-Au ('central')collisions are compared to
experimental data available from CERN experiments and also with recent
theoretical estimations given by others models. Neutral strange particle
abundances are quite well described for p-p,N-N and p-A interactions ,but are
underpredicted by a factor of two in A-A interactions for
in symmetric collisions(S-S,\,\,Pb-Pb)and for
in asymmetric ones(S-Ag,\,\,S-Au,\,\,S-W). A
qualitative prediction for rapidity, transverse kinetic energy and transverse
momenta normalized distributions are performed at 200 GeV/Nucleon in
p-S,S-S,S-Ag and S-Au collisions in comparison with recent experimental data.
HIJING model predictions for coming experiments at CERN for S-Au, S-W and Pb-Pb
interactions are given. The theoretical calculations are estimated in a full
phase space.Comment: 33 pages(LATEX),18 figures not included,available in hard copy upon
request , Dipartamento di Fisica Padova,report DFPD-94-NP-4
Electrostatic tailoring of magnetic interference in quantum point contact ballistic Josephson junctions
The magneto-electrostatic tailoring of the supercurrent in quantum point
contact ballistic Josephson junctions is demonstrated. An etched InAs-based
heterostructure is laterally contacted to superconducting niobium leads and the
existence of two etched side gates permits, in combination with the application
of a perpendicular magnetic field, to modify continuously the magnetic
interference pattern by depleting the weak link. For wider junctions the
supercurrent presents a Fraunhofer-like interference pattern with periodicity
h/2e whereas by shrinking electrostatically the weak link, the periodicity
evolves continuously to a monotonic decay. These devices represent novel
tunable structures that might lead to the study of the elusive Majorana
fermions.Comment: 4.5 pages, 4 color figure
Spin mapping, phase diagram, and collective modes in double layer quantum Hall systems at
An exact spin mapping is identified to simplify the recently proposed
hard-core boson description (Demler and Das Sarma, Phys. Rev. Lett., to be
published) of the bilayer quantum Hall system at filling factor 2. The
effective spin model describes an easy-plane ferromagnet subject to an external
Zeeman field. The phase diagram of this effective model is determined exactly
and found to agree with the approximate calculation of Demler and Das Sarma,
while the Goldstone-mode spectrum, order parameter stiffness and
Kosterlitz-Thouless temperature in the canted antiferromagnetic phase are
computed approximately.Comment: 4 pages with 2 figures include
Singlet-triplet transition in a few-electron lateral InGaAs-InAlAs quantum dot
The magnetic-field evolution of Coulomb blockade peaks in lateral
InGaAs/InAlAs quantum dots in the few-electron regime is reported. Quantum dots
are defined by gates evaporated onto a 60 nm-thick hydrogen silsesquioxane
insulating film. A gyromagnetic factor of 4.4 is measured via zero-bias spin
spectroscopy and a transition from singlet to triplet spin configuration is
found at an in-plane magnetic field B = 0.7 T. This observation opens the way
to the manipulation of singlet and triplet states at moderate fields and its
relevance for quantum information applications will be discussed.Comment: 4 pages, 3 figure
Direct measurements of the fractional quantum Hall effect gaps
We measure the chemical potential jump across the fractional gap in the
low-temperature limit in the two-dimensional electron system of GaAs/AlGaAs
single heterojunctions. In the fully spin-polarized regime, the gap for filling
factor nu=1/3 increases LINEARLY with magnetic field and is coincident with
that for nu=2/3, reflecting the electron-hole symmetry in the spin-split Landau
level. In low magnetic fields, at the ground-state spin transition for nu=2/3,
a correlated behavior of the nu=1/3 and nu=2/3 gaps is observed
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