5,485 research outputs found
Bifurcations in Boltzmann-Langevin One Body dynamics for fermionic systems
We investigate the occurrence of bifurcations in the dynamical trajectories
depicting central nuclear collisions at Fermi energies. The quantitative
description of the reaction dynamics is obtained within a new transport model,
based on the solution of the Boltzmann-Langevin equation in three dimensions,
with a broad applicability for dissipative fermionic dynamics. Dilute systems
formed in central collisions are shown to fluctuate between two energetically
favourable mechanisms: reverting to a compact shape or rather disintegrating
into several fragments. The latter result can be connected to the recent
observation of bimodal distributions for quantities characterising
fragmentation processes and may suggest new investigations
Multifragmentation of charge asymmetric nuclear systems
The multifragmentation of excited spherical nuclear sources with various N/Z
ratios and fixed mass number is studied within dynamical and statistical
models. The dynamical model treats the multifragmentation process as a final
stage of the growth of density fluctuations in unstable expanding nuclear
matter. The statistical model makes a choice of the final multifragment
configuration according to its statistical weight at a global thermal
equilibrium. Similarities and differences in the predictions of the two models
on the isotopic composition of the produced fragments are presented and the
most sensitive observable characteristics are discussed.Comment: 15 pages, 8 figure
Inhomogeneity growth in two-component fermionic systems
The dynamics of fermionic many-body systems is investigated in the framework
of Boltzmann-Langevin (BL) stochastic one-body approaches. Within the recently
introduced BLOB model, we examine the interplay between mean-field effects and
two-body correlations, of stochastic nature, for nuclear matter at moderate
temperature and in several density conditions, corresponding to stable or
mechanically unstable situations. Numerical results are compared to analytic
expectations for the fluctuation amplitude of isoscalar and isovector
densities, probing the link to the properties of the employed effective
interaction, namely symmetry energy (for isovector modes) and incompressibility
(for isoscalar modes). For unstable systems, clusterization is observed. The
associated features are compared to analytical results for the typical length
and time scales characterizing the growth of unstable modes in nuclear matter
and for the isotopic variance of the emerging fragments. We show that the BLOB
model is generally better suited than simplified approaches previously
introduced to solve the BL equation, and it is therefore more advantageous in
applications to open systems, like heavy ion collisions.Comment: 19 pages, 13 figure
Frustrated fragmentation and re-aggregation in nuclei: a non-equilibrium description in spallation
Heavy nuclei bombarded with protons and deuterons in the 1 GeV range have a
large probability of undergoing a process of evaporation and fission; less
frequently, the prompt emission of few intermediate-mass fragments can also be
observed.
We employ a recently developed microscopic approach, based on the
Boltzmann-Langevin transport equation, to investigate the role of mean-field
dynamics and phase-space fluctuations in these reactions.
We find that the formation of few IMF's can be confused with asymmetric
fission when relying on yield observables, but it can not be assimilated to the
statistical decay of a compound nucleus when analysing the dynamics and
kinematic observables: it can be described as a fragmentation process initiated
by phase-space fluctuations, and successively frustrated by the mean-field
resilience. As an extreme situation, which corresponds to non-negligible
probability, the number of fragments in the exit channel reduces to two, so
that fission-like events are obtained by re-aggregation processes.
This interpretation, inspired by nuclear-spallation experiments, can be
generalised to heavy-ion collisions from Fermi to relativistic energies, for
situations when the system is closely approaching the fragmentation threshold
On the splitting of nucleon effective masses at high isospin density: reaction observables
We review the present status of the nucleon effective mass splitting
in asymmetric matter, with controversial predictions within both
non-relativistic relativistic approaches to the effective in medium
interactions. Based on microscopic transport simulations we suggest some rather
sensitive observables in collisions of asymmetric (unstable) ions at
intermediate () energies: i) Energy systematics of Lane Potentials; ii)
Isospin content of fast emitted nucleons; iii) Differential Collective Flows.
Similar measurements for light isobars (like ) could be also
important.Comment: 13 pages, 10 figures; NSCL/RIA Workshop on "Reaction Mechanisms for
Rare Isotope Beams", March 2005, AIP Proc. Latex Styl
Non-Markovian source term for particle production by a self-interacting scalar field in the large-N approximation
The particle production in the self-interacting N-component complex scalar
field theory is studied at large N. A non-Markovian source term that includes
all higher order back-reaction and collision effects is derived. The kinetic
amplitudes accounting for the change in the particle number density caused by
collisions are obtained. It is shown that the production of particles is
symmetric in the momentum space. The problem of renormalization is briefly
discussed.Comment: minor changes, journal versio
Bifurcations in dissipative fermionic dynamics
The Boltzmann-Langevin One-Body model (BLOB), is a novel one-body transport
approach, based on the solution of the Boltzmann-Langevin equation in three
dimensions; it is used to handle large-amplitude phase-space fluctuations and
has a broad applicability for dissipative fermionic dynamics. We study the
occurrence of bifurcations in the dynamical trajectories describing heavy-ion
collisions at Fermi energies.
The model, applied to dilute systems formed in such collisions, reveals to be
closer to the observation than previous attempts to include a Langevin term in
Boltzmann theories. The onset of bifurcations and bimodal behaviour in
dynamical trajectories, determines the fragment-formation mechanism. In
particular, in the proximity of a threshold, fluctuations between two
energetically favourable mechanisms stand out, so that when evolving from the
same entrance channel, a variety of exit channels is accessible.
This description gives quantitative indications about two threshold
situations which characterise heavy-ion collisions at Fermi energies. First,
the fusion-to-multifragmentation threshold in central collisions, where the
system either reverts to a compact shape, or splits into several pieces of
similar sizes. Second, the transition from binary mechanisms to neck
fragmentation (in general, ternary channels), in peripheral collisions.Comment: Conf. proc. ECHIC November 6-8, 2013 Messina (Italy
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