591 research outputs found
R-Process Nucleosynthesis In Neutrino-Driven Winds From A Typical Neutron Star With M = 1.4 Msun
We study the effects of the outer boundary conditions in neutrino-driven
winds on the r-process nucleosynthesis. We perform numerical simulations of
hydrodynamics of neutrino-driven winds and nuclear reaction network
calculations of the r-process. As an outer boundary condition of hydrodynamic
calculations, we set a pressure upon the outermost layer of the wind, which is
approaching toward the shock wall. Varying the boundary pressure, we obtain
various asymptotic thermal temperature of expanding material in the
neutrino-driven winds for resulting nucleosynthesis. We find that the
asymptotic temperature slightly lower than those used in the previous studies
of the neutrino-driven winds can lead to a successful r-process abundance
pattern, which is in a reasonable agreement with the solar system r-process
abundance pattern even for the typical proto-neutron star mass Mns ~ 1.4 Msun.
A slightly lower asymptotic temperature reduces the charged particle reaction
rates and the resulting amount of seed elements and lead to a high
neutron-to-seed ratio for successful r-process. This is a new idea which is
different from the previous models of neutrino-driven winds from very massive
(Mns ~ 2.0 Msun) and compact (Rns ~ 10 km) neutron star to get a short
expansion time and a high entropy for a successful r-process abundance pattern.
Although such a large mass is sometimes criticized from observational facts on
a neutron star mass, we dissolve this criticism by reconsidering the boundary
condition of the wind. We also explore the relation between the boundary
condition and neutron star mass, which is related to the progenitor mass, for
successful r-process.Comment: 14 pages, 2 figure
Constraining the Spectrum of Supernova Neutrinos from v-Process Induced Light Element Synthesis
We constrain energy spectra of supernova neutrinos through the avoidance of an overproduction of the 11B abundance during Galactic chemical evolution. In supernova nucleosynthesis calculations with a parametrized neutrino spectrum as a function of temperature of νµ,τ and ¯ νµ,τ and total neutrino energy, we find a strong neutrino temperature dependence of the 11B yield. When the yield is combined with observed abundances, the acceptable range of the νµ,τ and ¯νµ,τ temperature is found to be 4.8 to 6.6 MeV. Nonzero neutrino chemical potentials would reduce this temperature range by about 10% for a degeneracy parameter ην = µν/kTν smaller than 3
Neutrino oscillation and expected event rate of supernova neutrinos in adiabatic explosion model
We study how the influence of the shock wave appears in neutrino oscillations
and the neutrino spectrum using density profile of adiabatic explosion model of
a core-collapse supernova which is calculated in an implicit Lagrangian code
for general relativistic spherical hydrodynamics. We calculate expected event
rates of neutrino detection at SK and SNO for various theta_{13} values and
both normal and inverted hierarchies. The predicted event rates of bar{nu}_e
and nu_e depend on the mixing angle theta_{13} for the inverted and normal
hierarchies, respectively, and the influence of the shock appears for about 2 -
8 s when sin^2 2 theta_{13} is larger than 10^{-3}. These neutrino signals for
the shock propagation is decreased by < 30 % for bar{nu}_e in inverted (SK) or
by < 15 % for nu_e in normal hierarchy (SNO) compared with the case without
shock. The obtained ratio of the total event for high-energy neutrinos (20 MeV
< E_{nu} < 60 MeV) to low-energy neutrinos (5 MeV < E_{nu} < 20 MeV) is
consistent with the previous studies in schematic semi-analytic or other
hydrodynamic models of the shock propagation. The time dependence of the
calculated ratio of the event rates of high-energy to low-energy neutrinos is a
very useful observable which is sensitive to theta_{13} and hierarchies.
Namely, time-dependent ratio shows clearer signal of the shock propagation that
exhibits remarkable decrease by at most factor \sim 2 for bar{nu}_e in inverted
(SK), whereas it exhibits smaller change by \sim 10 % for nu_e in normal
hierarchy (SNO). Observing time-dependent high-energy to low-energy ratio of
the neutrino events thus would provide a piece of very useful information to
constrain theta_{13} and mass hierarchy, and eventually help understanding the
propagation how the shock wave propagates inside the star.Comment: 19 pages, 9 figures, accepted for publication in Physical Review
Astrophysical reaction rate for Be by photodisintegration
We study the astrophysical reaction rate for the formation of Be
through the three body reaction . This reaction is one
of the key reactions which could bridge the mass gap at A = 8 nuclear systems
to produce intermediate-to-heavy mass elements in alpha- and neutron-rich
environments such as r-process nucleosynthesis in supernova explosions,
s-process nucleosynthesis in asymptotic giant branch (AGB) stars, and
primordial nucleosynthesis in baryon inhomogeneous cosmological models. To
calculate the thermonuclear reaction rate in a wide range of temperatures, we
numerically integrate the thermal average of cross sections assuming a
two-steps formation through a metastable Be. Off-resonant and on-resonant
contributions from the ground state in Be are taken into account. As
input cross section, we adopt the latest experimental data by
photodisintegration of Be with laser-electron photon beams, which covers
all relevant resonances in Be. We provide the reaction rate for
Be in the temperature range from T=10
to T=10 both in the tabular form and in the analytical form. The
calculated reaction rate is compared with the reaction rates of the CF88 and
the NACRE compilations. The CF88 rate is valid at due to lack
of the off-resonant contribution. The CF88 rate differs from the present rate
by a factor of two in a temperature range . The NACRE rate,
which adopted different sources of experimental information on resonance states
in Be, is 4--12 times larger than the present rate at ,
but is consistent with the present rate to within at .Comment: 32 pages (incl 6 figures), Nucl. Phys. in pres
Alpha scattering and capture reactions in the A = 7 system at low energies
Differential cross sections for He- scattering were measured in
the energy range up to 3 MeV. These data together with other available
experimental results for He and H scattering were
analyzed in the framework of the optical model using double-folded potentials.
The optical potentials obtained were used to calculate the astrophysical
S-factors of the capture reactions HeBe and
HLi, and the branching ratios for the transitions into
the two final Be and Li bound states, respectively. For
HeBe excellent agreement between calculated and
experimental data is obtained. For HLi a value
has been found which is a factor of about 1.5 larger than the adopted value.
For both capture reactions a similar branching ratio of has been obtained.Comment: submitted to Phys.Rev.C, 34 pages, figures available from one of the
authors, LaTeX with RevTeX, IK-TUW-Preprint 930540
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