1,674 research outputs found
The boson-fermion model: An exact diagonalization study
The main features of a generic boson-fermion scenario for electron pairing in
a many-body correlated fermionic system are: i) a cross-over from a poor metal
to an insulator and finally a superconductor as the temperature decreases, ii)
the build-up of a finite amplitude of local electron pairing below a certain
temperature , followed by the onset of long-range phase correlations among
electron pairs below a second characteristic temperature , iii) the
opening of a pseudogap in the DOS of the electrons below , rendering these
electrons poorer and poorer quasi-particles as the temperature decreases, with
the electron transport becoming ensured by electron pairs rather than by
individual electrons. A number of these features have been so far obtained on
the basis of different many-body techniques, all of which have their built-in
shortcomings in the intermediate coupling regime, which is of interest here. In
order to substantiate these features, we investigate them on the basis of an
exact diagonalization study on rings up to eight sites. Particular emphasis has
been put on the possibility of having persistent currents in mesoscopic rings
tracking the change-over from single- to two-particle transport as the
temperature decreases and the superconducting state is approached.Comment: 7 pages, 8 figures; to be published in Phys. Rev.
Doping dependence of magnetic excitations of 1D cuprates as probed by Resonant Inelastic x-ray Scattering
We study the dynamical, momentum dependent two- and four-spin response
functions in doped and undoped 1D cuprates, as probed by resonant inelastic
x-ray scattering, using an exact numerical diagonalization procedure. In the
undoped system the four-spin response vanishes at , whereas the
two-spin correlator is peaked around , with generally larger spectral
weight. Upon doping spectra tend to soften and broaden, with a transfer of
spectral weight towards higher energy. However, the total spectral weight and
average peak position of either response are only weakly affected by doping up
to a concentration of 1/8. Only the two-spin response at changes
strongly, with a large reduction of spectral weight and enhancement of
excitation energy. At other momenta the higher-energy, generic features of the
magnetic response are robust against doping. It signals the presence of strong
short-range antiferromagnetic correlations, even after doping mobile holes into
the system. We expect this to hold also in higher dimensions.Comment: 7 pages, 5 figure
Effect of magnetic fluctuations on the normal state properties of Sr_2RuO_4
We investigate the normal state transport properties of SrRuO and we
show that a consistent explanation of the experimental results can be obtained
assuming that the system is near a quantum phase transition. Within the
framework of a self-consistent spin fluctuation theory, we calculate the
temperature variation of some relevant physical quantities and we discuss a
possible microscopic origin of the quantum phase transition.Comment: 5 pages, 4 figures, to appear on Europhysics Letter
Competition between magnetic and superconducting pairing exchange interactions in confined systems
We analyze the competition between magnetic and pairing interactions in confined systems relevant to either small superconducting grains or trapped ultracold atomic gases. The response to the imbalance of the chemical potential for the two spin states leads to various inhomogeneous profiles of the pair energy distribution. We show that the position in the energy spectrum for the unpaired particles can be tuned by varying the filling or the pairing strength. When small grains are considered, the antiferromagnetic exchange stabilizes the pair correlations, whereas for Fermi gases, a transition from a mixed configuration to a phase-separated one beyond a critical polarization threshold appears, as does an unconventional phase with a paired shell around a normal core
On line power spectra identification and whitening for the noise in interferometric gravitational wave detectors
In this paper we address both to the problem of identifying the noise Power
Spectral Density of interferometric detectors by parametric techniques and to
the problem of the whitening procedure of the sequence of data. We will
concentrate the study on a Power Spectral Density like the one of the
Italian-French detector VIRGO and we show that with a reasonable finite number
of parameters we succeed in modeling a spectrum like the theoretical one of
VIRGO, reproducing all its features. We propose also the use of adaptive
techniques to identify and to whiten on line the data of interferometric
detectors. We analyze the behavior of the adaptive techniques in the field of
stochastic gradient and in the
Least Squares ones.Comment: 28 pages, 21 figures, uses iopart.cls accepted for pubblication on
Classical and Quantum Gravit
Spin-orbital polarization of Majorana edge states in oxides nanowires
We investigate a paradigmatic case of topological superconductivity in a
one-dimensional nanowire with orbitals and a strong interplay of
spin-orbital degrees of freedom due to the competition of orbital Rashba
interaction, atomic spin-orbit coupling, and structural distortions. We
demonstrate that the resulting electronic structure exhibits an orbital
dependent magnetic anisotropy which affects the topological phase diagram and
the character of the Majorana bound states (MBSs). The inspection of the
electronic component of the MBSs reveals that the spin-orbital polarization
generally occurs along the direction of the applied Zeeeman magnetic field, and
transverse to the magnetic and orbital Rashba fields. The competition of
symmetric and antisymmetric spin-orbit coupling remarkably leads to a
misalignment of the spin and orbital moments transverse to the orbital Rashba
fields, whose manifestation is essentially orbital dependent. The behavior of
the spin-orbital polarization along the applied Zeeman field reflects the
presence of multiple Fermi points with inequivalent orbital character in the
normal state. Additionally, the response to variation of the electronic
parameters related with the degree of spin-orbital entanglement leads to
distinctive evolution of the spin-orbital polarization of the MBSs. These
findings unveil novel paths to single-out hallmarks relevant for the
experimental detection of MBSs.Comment: 14 pages, 8 figure
Inverse Proximity Effects at Spin-Triplet Superconductor-Ferromagnet Interface
We investigate inverse proximity effects in a spin-triplet superconductor
(TSC) interfaced with a ferromagnet (FM), assuming different types of magnetic
profiles and chiral or helical pairings. The region of the coexistence of
spin-triplet superconductivity and magnetism is significantly influenced by the
orientation and spatial extension of the magnetization with respect to the spin
configuration of the Cooper pairs, resulting into clearcut anisotropy
signatures. A characteristic mark of the inverse proximity effect arises in the
induced spin-polarization at the TSC interface. This is unexpectedly stronger
when the magnetic proximity is weaker, thus unveiling immediate detection
signatures for spin-triplet pairs. We show that an anomalous magnetic proximity
can occur at the interface between the itinerant ferromagnet, SrRuO, and
the unconventional superconductor SrRuO. Such scenario indicates the
potential to design characteristic inverse proximity effects in experimentally
available SrRuO-SrRuO heterostructures and to assess the occurrence
of spin-triplet pairs in the highly debated superconducting phase of
SrRuO.Comment: 11 pages, 6 figure
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