11,506 research outputs found
Nuclear electromagnetic dipole response with the Self-Consistent Green's Function formalism
Microscopic calculations of the electromagnetic response of medium-mass
nuclei are now feasible thanks to the availability of realistic nuclear
interactions with accurate saturation and spectroscopic properties, and the
development of large-scale computing methods for many-body physics. The purpose
is to compute isovector dipole electromagnetic (E1) response and related
quantities, i.e. integrated dipole cross section and polarizability, and
compare with data from photoabsorption and Coulomb excitation experiments. The
single-particle propagator is obtained by solving the Dyson equation, where the
self-energy includes correlations non-perturbatively through the Algebraic
Diagrammatic Construction (ADC) method. The particle-hole () polarization
propagator is treated in the Dressed Random Phase Approximation (DRPA), based
on an effective correlated propagator that includes some effects but
keeps the same computation scaling as the standard Hartree-Fock propagator. The
E1 responses for O, Ca and Ni have
been computed: the presence of a soft dipole mode of excitation for
neutron-rich nuclei is found, and there is a fair reproduction of the
low-energy part of the experimental excitation spectrum. This is reflected in a
good agreement with the empirical dipole polarizability values. For a realistic
interaction with an accurate reproduction of masses and radii up to medium-mass
nuclei, the Self-Consistent Green's Function method provides a good description
of the E1 response, especially in the part of the excitation spectrum below the
Giant Dipole Resonance. The dipole polarizability is largely independent from
the strategy of mapping the dressed propagator to a simplified one that is
computationally manageableComment: 14 pages, 12 figure
U(2) Flavor Physics without U(2) Symmetry
We present a model of fermion masses based on a minimal, non-Abelian discrete
symmetry that reproduces the Yukawa matrices usually associated with U(2)
theories of flavor. Mass and mixing angle relations that follow from the simple
form of the quark and charged lepton Yukawa textures are therefore common to
both theories. We show that the differing representation structure of our
horizontal symmetry allows for new solutions to the solar and atmospheric
neutrino problems that do not involve modification of the original charged
fermion Yukawa textures, or the introduction of sterile neutrinos.Comment: 12 pages RevTeX, 1 eps figure. A few typos correcte
Electroweak Precision Tests: A Concise Review
1. Introduction 2. Status of the Data 3. Precision Electroweak Data and the
Standard Model 4. A More General Analysis of Electroweak Data
4.1 Basic Definitions and Results
4.2 Experimental Determination of the Epsilon Variables
4.3 Comparing the Data with the Minimal Supersymmetric Standard Model 5.
Theoretical Limits on the Higgs Mass 6. ConclusionComment: Submitted to Int. Journal of Modern Physics
Ogus realization of 1-motives
After introducing the Ogus realization of 1-motives we prove that it is a
fully faithful functor. More precisely, following a framework introduced by
Ogus, considering an enriched structure on the de Rham realization of 1-motives
over a number field, we show that it yields a full functor by making use of an
algebraicity theorem of Bost
Method to measure off-axis displacements based on the analysis of the intensity distribution of a vortex beam
We study the properties of the Fraunhofer diffraction patterns produced by
Gaussian beams crossing spiral phase plates. We show, both analytically and
numerically, that off-axis displacements of the input beam produce asymmetric
diffraction patterns. The intensity profile along the direction of maximum
asymmetry shows two different peaks. We find that the intensity ratio between
these two peaks decreases exponentially with the off-axis displacement of the
incident beam, the decay being steeper for higher strengths of the optical
singularity of the spiral phase plate. We analyze how this intensity ratio can
be used to measure small misalignments of the input beam with a very high
precision.Comment: 8 pages, 4 figures. Accepted for publication in PR
Generation of polarization entangled photon pairs by a single crystal interferometric source pumped by femtosecond laser pulses
Photon pairs, highly entangled in polarization have been generated under
femtosecond laser pulse excitation by a type I crystal source, operating in a
single arm interferometric scheme. The relevant effects of temporal walk-off
existing in these conditions between the ordinary and extraordinary photons
were experimentally investigated. By introducing a suitable temporal
compensation between the two orthogonal polarization components highly
entangled pulsed states were obtained
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