2,399 research outputs found
Correlation effects in quasi one dimensional electron wires
We explore the role of electron correlation in quasi one dimensional quantum
wires as the range of the interaction potential is changed and their thickness
is varied by performing exact quantum Monte Carlo simulations at various
electronic densities. In the case of unscreened interactions with a long range
1/x tail there is a crossover from a liquid to a quasi Wigner crystal state as
the density decreases. When this interaction is screened, quasi long range
order is prevented from forming, although a significant correlation with 4 k_F
periodicity is still present at low densities. At even lower electron
concentration, exchange is suppressed and the spin-dependent interactions
become negligible, making the electrons behave like spinless fermions. We show
that this behavior is shared by the long range and screened interactions by
studying the spin and charge excitations of the system in both cases. Finally,
we study the effect of electron correlations in the double quantum wire
experiment [Steinberg et al., Phys. Rev. B 77, 113307 (2006)], by introducing
an accurate model for the screening in the experiment and explicitly including
the finite length of the system in our simulations. We find that decreasing the
electron density drives the system from a liquid to a state with quite strong 4
k_F correlations. This crossover takes place around , the
density where the electron localization occurs in the experiment. The charge
and spin velocities are also in remarkable agreement with the experimental
findings in the proximity of the crossover. We argue that correlation effects
play an important role at the onset of the localization transition.Comment: minor improvements, 13 pages, 12 figure
Growing CeO2 Nanoparticles Within the Nano-Porous Architecture of the SiO2 Aerogel
In this study, new CeO2-SiO2 aerogel nanocomposites obtained by controlled growth of CeO2 nanoparticles within the highly porous matrix of a SiO2 aerogel are presented. The nanocomposites have been synthesized via a sol-gel route, employing cerium (III) nitrate as the CeO2 precursor and selected surfactants to control the growth of the CeO2 nanoparticles, which occurs during the supercritical drying of the aerogels. Samples with different loading of the CeO2 dispersed phase, ranging from 5 to 15%, were obtained. The nanocomposites showed the morphological features typical of the SiO2 aerogels such as open mesoporosity with surface area values up to 430 m2·g−1. TEM and XRD characterizations show that nanocrystals of the dispersed CeO2 nanophase grow within the aerogel already during the supercritical drying process, with particle sizes in the range of 3 to 5 nm. TEM in particular shows that the CeO2 nanoparticles are well-distributed within the aerogel matrix. We also demonstrate the stability of the nanocomposites under high temperature conditions, performing thermal treatments in air at 450 and 900°C. Interestingly, the CeO2 nanoparticles undergo a very limited crystal growth, with sizes up to only 7 nm in the case of the sample subjected to a 900°C treatment
Hexatic and mesoscopic phases in the 2D quantum Coulomb system
We study the Wigner crystal melting in a two dimensional quantum system of
particles interacting via the 1/r Coulomb potential. We use quantum Monte Carlo
methods to calculate its phase diagram, locate the Wigner crystal region, and
analyze its instabilities towards the liquid phase. We discuss the role of
quantum effects in the critical behavior of the system, and compare our
numerical results with the classical theory of melting, and the microemulsion
theory of frustrated Coulomb systems. We find a Pomeranchuk effect much larger
then in solid helium. In addition, we find that the exponent for the algebraic
decay of the hexatic phase differs significantly from the Kosterilitz-Thouless
theory of melting. We search for the existence of mesoscopic phases and find
evidence of metastable bubbles but no mesoscopic phase that is stable in
equilibrium
Alcuni esempi di catalogazione e restauro nell’ambito della Collezione Storica degli Strumenti di Fisica dell’Università di Palermo
In questo articolo presenteremo e discuteremo della catalogazione e restauro e di alcuni strumenti scientifici di particolare interesse storico-didattico appartenenti alla Collezione Storica degli Strumenti di Fisica dell’Università di Palermo. La catalogazione è stata effettuata secondo le indicazioni fornite dell’Istituto Centrale per il Catalogo e la Documentazione, per mezzo della scheda per il patrimonio scientifico-tecnologico. Nell’articolo saranno discussi gli aspetti tecnici degli interventi di restauro effettuati e saranno indicate le linee guida generali per il proseguimento dell’attività avviata.The article deals with the cataloguing and restoration of some scientific instruments of particular historical and didactic interest belonging to the Historical Collection of the Physics Instruments of the University of Palermo. The restoration activities have been carried out side by side the cataloguing, which has been done following the instructions supplied by the Central Institute for Cataloguing and Documentation with the official form for the scientific and technological heritage. In the article, we will discuss the technical aspects of the work carried out and basic guidelines will be given for the continuation of the activity
The Ultrasonic Field of Focused Trandsucers Through a Liquid-Solid Interface
This paper presents theoretical and experimental results on the ultrasonic field of focused immersion transducers. The French Atomic Energy Commission (C.E.A.) has developed a software which calculates the ultrasonic field produced by a focused (or unfocused) transducer through a liquid-solid interface at normal or oblique incidence. The radiation of the transducer is formulated by the method of the Rayleigh integral, extended to take into account the liquid-solid interface. Firstly we describe this model, then we present measurements of the ultrasonic field produced by focused transducers in steel blocks. Experiments have been made using, at low frequencies, an electrodynamic probe, and, at high frequencies, an optical probe
Dynamical screening in strongly correlated metal SrVO3
The consequences of dynamical screening of Coulomb interaction among
correlated electrons in realistic materials have not been widely considered
before. In this letter we try to incorporate a frequency dependent Coulomb
interaction into the state-of-the-art ab initio electronic structure computing
framework of local density approximation plus dynamical mean-field theory, and
then choose SrVO3 as a prototype material to demonstrate the importance of
dynamical screening effect. It is shown to renormalise the spectral weight near
the Fermi level, to increase the effective mass, and to suppress the t2g
quasiparticle band width apparently. The calculated results are in accordance
with very recent angle-resolved photoemission spectroscopy experiments and Bose
factor ansatz calculations.Comment: 6 pages, 4 figures. arXiv admin note: text overlap with
arXiv:1107.312
Insights into the Structure of Dot@Rod and Dot@Octapod CdSe@CdS Heterostructures
CdSe@CdS dot@rods with diameter around 6 nm and length of either
20, 27, or 30 nm and dot@octapods with pod diameters of ?15 nm and lengths of ?50
nm were investigated by X-ray absorption spectroscopy. These heterostructures are
prepared by seed-mediated routes, where the structure, composition, and morphology of
the CdSe nanocrystals used as a seed play key roles in directing the growth of the second
semiconducting domain. The local structural environment of all the elements in the
CdSe@CdS heterostructures was investigated at the Cd, S, and Se K-edges by taking
advantage of the selectivity of X-ray absorption spectroscopy, and was compared to pure
reference compounds. We found that the structural features of dot@rods are
independent of the size of the rods. These structures can be described as made of a
CdSe dot and a CdS rod, both in the wurtzite phase with a high crystallinity of both the
core and the rod. This result supports the effectiveness of high temperature colloidal
synthesis in promoting the formation of core@shell nanocrystals with very low
defectivity. On the other hand, data on the CdSe@CdS with octapod morphology suggest the occurrence of a core composed of
a CdSe cubic sphalerite phase with eight pods made of CdS wurtzite phase. Our findings are compared to current models
proposed for the design of functional heterostructures with controlled nanoarchitecture
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