68,951 research outputs found
Origin of Borromean systems
The complex energies of the three-body resonances for one infinitely heavy
particle and two non-interacting light particles are the sum of the two
contributing two-body complex resonance energies. The bound state of a
Borromean system originates from a resonance when the third interaction is
introduced, a finite mass is allowed and proper angular momentum coupling is
included. The relative importance of these contributions are investigated and
the resulting structure of Borromean systems are traced back to the two-body
continuum properties. The and states in He result from
neutron-core p-states and the ground and first excited state of Li
originate from neutron-core and -states.Comment: Physics Letters B, in pres
Momentum distributions and reaction mechanisms for breakup of two--neutron halos
A theoretical model able to describe fragmentation reactions of three--body
halo nuclei on different targets, from light to heavy, is used to compute
neutron and core momentum distributions. Both Coulomb and nuclear interactions
are simultaneously included. We specify the different reaction mechanisms
related to various processes. The method is applied to fragmentation of He
and Li on C and Pb. We find good agreement with the available
experimental results.Comment: 10 pages, 3 figures, Phys.Lett.B in pres
The Desirable Organizational Structure for Evolutionary Firms in Static Landscapes
In addition to the common analysis of the Kauffman NK model where the value of K and the structure of interaction is given, the aim of this paper is to study what would be the values of these two parameters if they were endogenized. Thus, a model is proposed where firms and business schools coordinate to search for high peaks in their respective landscapes using evolutionary algorithms. The main result coming out from the analysis of the model is that agents, using evolutionary algorithms, attempt to simplify the problems of coordination and this, over time, produces the existence in the economy of agents using many different strategies. (JEL-code: C61, C63, D21, D23
On the congruence subgroup problem for branch groups
We answer a question of Bartholdi, Siegenthaler and Zalesskii, showing that
the congruence subgroup problem for branch groups is independent of the branch
action on a tree. We prove that the congruence topology of a branch group is
determined by the group; specifically, by its structure graph, an object first
introduced by Wilson. We also give a more natural definition of this graph.Comment: 9 pages, no figures; minor changes in accordance with referee report,
exposition improve
Three-body structure of the low-lying Ne-states
The Borromean nucleus Ne (O) is investigated by using
the hyperspheric adiabatic expansion for a a three-body system. The measured
size of O and the low-lying resonances of F (O) are
first used as constraints to determine both central and spin-dependent two-body
interactions. Then, the ground state structure of Ne is found to be an
almost equal mixture of and proton-O relative states, the
two lowest excited states have about 80% of -mixed components, and for the
next two excited three-body states the proton-O relative s-states do not
contribute. The spatial extension is as in ordinary nuclei. The widths of the
resonances are estimated by the WKB transmission through the adiabatic
potentials and found in agreement with the established experimental limits. We
compare with experimental information and previous works.Comment: 29 pages, 7 postscript figures, to be published in Nuclear Physics
Isospin mixing and energy distributions in three-body decay
The structure of the second 2 resonance in Li is investigated with
special emphasis on its isospin 0 components. The wave functions are computed
in a three-body model (++) using the hyperspherical adiabatic
expansion method combined with complex scaling. In the decay into three free
particles the symmetry conserving short-range interaction dominates at short
distance whereas the symmetry breaking Coulomb interaction dominates at
intermediate and large distances resulting in substantial isospin mixing. We
predict the mixing and the energy distributions of the fragments after decay.
Computations are consistent with available experiments. We conjecture that
nuclear three-body decays frequently produce such large isospin mixing at large
distance where the energy distributions. are determined.Comment: 5 pages, 4 figures, to be published in Physics Letters
Resonances in three-body systems with short and long-range interactions
The complex scaling method permits calculations of few-body resonances with
the correct asymptotic behaviour using a simple box boundary condition at a
sufficiently large distance. This is also valid for systems involving more than
one charged particle. We first apply the method on two-body systems. Three-body
systems are then investigated by use of the (complex scaled) hyperspheric
adiabatic expansion method. The case of the 2 resonance in Be and
Li is considered. Radial wave functions are obtained showing the correct
asymptotic behaviour at intermediate values of the hyperradii, where wave
functions can be computed fully numerically.Comment: invited talk at the 18th International Conference on Few-Body
Problems in Physics, Santos-S.Paulo, August 21-26, 200
A Comparative Analysis of Self-Rectifying Turbines for the Mutriku Oscillating Water Column Energy Plant
Oscillating Water Column (OWC) based devices are arising as one of the most promising technologies for wave energy harnessing. However, the most widely used turbine comprising its power take-off (PTO) module, the Wells turbine, presents some drawbacks that require special attention. Notwithstanding different control strategies are being followed to overcome these issues; the use of other self-rectifying turbines could directly achieve this goal at the expense of some extra construction, maintenance, and operation costs. However, these newly developed turbines in turn show diverse behaviours that should be compared for each case. This paper aims to analyse this comparison for the Mutriku wave energy power plant.This work was supported by the MINECO through the
Research Project DPI2015-70075-R (MINECO/FEDER, UE)
and in part by the University of the Basque Country
(UPV/EHU) through PPG17/33. The authors would like to
thank the collaboration of the Basque Energy Agency (EVE)
through Agreement UPV/EHUEVE23/6/2011, the Spanish
National Fusion Laboratory (EURATOM-CIEMAT) through
Agreement UPV/EHUCIEMAT08/190, and EUSKAMPUSCampus
of International Excellence
Origin of three-body resonances
We expose the relation between the properties of the three-body continuum
states and their two-body subsystems. These properties refer to their bound and
virtual states and resonances, all defined as poles of the -matrix. For one
infinitely heavy core and two non-interacting light particles, the complex
energies of the three-body poles are the sum of the two two-body complex
pole-energies. These generic relations are modified by center-of-mass effects
which alone can produce a Borromean system. We show how the three-body states
evolve in He, Li, and Be when the nucleon-nucleon interaction is
continuously switched on. The schematic model is able to reproduce the main
properties in their spectra. Realistic calculations for these nuclei are shown
in detail for comparison. The implications of a core with non-zero spin are
investigated and illustrated for Ne (O+p+p). Dimensionless units
allow predictions for systems of different scales.Comment: 15 pages, 7 figure
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