219 research outputs found
Saturation with chiral interactions and consequences for finite nuclei
We explore the impact of nuclear matter saturation on the properties and
systematics of finite nuclei across the nuclear chart. Using the ab initio
in-medium similarity renormalization group (IM-SRG), we study ground-state
energies and charge radii of closed-shell nuclei from He to Ni,
based on a set of low-resolution two- and three-nucleon interactions that
predict realistic saturation properties. We first investigate in detail the
convergence properties of these Hamiltonians with respect to model-space
truncations for both two- and three-body interactions. We find one particular
interaction that reproduces well the ground-state energies of all closed-shell
nuclei studied. As expected from their saturation points relative to this
interaction, the other Hamiltonians underbind nuclei, but lead to a remarkably
similar systematics of ground-state energies. Extending our calculations to
complete isotopic chains in the and shells with the valence-space
IM-SRG, the same interaction reproduces not only experimental ground states but
two-neutron-separation energies and first excited states. We also
calculate radii with the valence-space IM-SRG for the first time. Since this
particular interaction saturates at too high density, charge radii are still
too small compared with experiment. Except for this underprediction, the radii
systematics is, however, well reproduced. Our results highlight the importance
of nuclear matter as a theoretical benchmark for the development of
next-generation chiral interactions.Comment: 11 pages, 15 figures, 1 tabl
Radii and binding energies in oxygen isotopes: a puzzle for nuclear forces
We present a systematic study of both nuclear radii and binding energies in
(even) oxygen isotopes from the valley of stability to the neutron drip line.
Both charge and matter radii are compared to state-of-the-art {\it ab initio}
calculations along with binding energy systematics. Experimental matter radii
are obtained through a complete evaluation of the available elastic proton
scattering data of oxygen isotopes. We show that, in spite of a good
reproduction of binding energies, {\it ab initio} calculations with
conventional nuclear interactions derived within chiral effective field theory
fail to provide a realistic description of charge and matter radii. A novel
version of two- and three-nucleon forces leads to considerable improvement of
the simultaneous description of the three observables for stable isotopes, but
shows deficiencies for the most neutron-rich systems. Thus, crucial challenges
related to the development of nuclear interactions remain.Comment: 6 pages, 5 figures, Submitted to Nature Physics, April 12th 2016;
first version (v1 Arxiv) Internal Report Preprint Irfu-18 December 2015. 6
p., 5 fig., Submitted to Physical Review Letters, April 29, May 3rd 2016; 2nd
version. Int. Rep. Irfu-24 May 2016. Published in PRL, 27 July 2016 with the
modified title (Radii and binding energies in oxygen isotopes: a challenge
for nuclear forces
Structure of the lightest tin isotopes
We link the structure of nuclei around Sn, the heaviest doubly magic
nucleus with equal neutron and proton numbers (), to nucleon-nucleon
() and three-nucleon () forces constrained by data of few-nucleon
systems. Our results indicate that Sn is doubly magic, and we predict
its quadrupole collectivity. We present precise computations of Sn
based on three-particle--two-hole excitations of Sn, and reproduce the
small splitting between the lowest and states. Our
results are consistent with the sparse available data.Comment: 8 pages, 4 figure
Ab initio calculations of neutrinoless decay refine neutrino mass limits
Neutrinos are perhaps the most elusive known particles in the universe. We
know they have some nonzero mass, but unlike all other particles, the absolute
scale remains unknown. In addition, their fundamental nature is uncertain; they
can either be their own antiparticles or exist as distinct neutrinos and
antineutrinos. The observation of the hypothetical process of neutrinoless
double-beta () decay would at once resolve both questions,
while providing a strong lead in understanding the abundance of matter over
antimatter in our universe. In the scenario of light-neutrino exchange, the
decay rate is governed by, and thereby linked to the effective mass of the
neutrino via, the theoretical nuclear matrix element (NME). In order to extract
the neutrino mass, if a discovery is made, or to assess the discovery potential
of next-generation searches, it is essential to obtain accurate NMEs for all
isotopes of experimental interest. However, two of the most important cases,
Te and Xe, lie in the heavy region and have only been
accessible to phenomenological nuclear models. In this work we utilize powerful
advances in ab initio nuclear theory to compute NMEs from the underlying
nuclear and weak forces driving this decay, including the recently discovered
short-range component. We find that ab initio NMEs are generally smaller than
those from nuclear models, challenging the expected reach of future ton-scale
searches as well as claims to probe the inverted hierarchy of neutrino masses.
With this step, ab initio calculations with theoretical uncertainties are now
feasible for all isotopes relevant for next-generation decay
experiments.Comment: 5 pages, 3 figures, supplemental material include
Discrepancy between experimental and theoretical -decay rates resolved from first principles
-decay, a process that changes a neutron into a proton (and vice
versa), is the dominant decay mode of atomic nuclei. This decay offers a unique
window to physics beyond the standard model, and is at the heart of
microphysical processes in stellar explosions and the synthesis of the elements
in the Universe. For 50 years, a central puzzle has been that observed
-decay rates are systematically smaller than theoretical predictions.
This was attributed to an apparent quenching of the fundamental coupling
constant 1.27 in the nucleus by a factor of about 0.75 compared
to the -decay of a free neutron. The origin of this quenching is
controversial and has so far eluded a first-principles theoretical
understanding. Here we address this puzzle and show that this quenching arises
to a large extent from the coupling of the weak force to two nucleons as well
as from strong correlations in the nucleus. We present state-of-the-art
computations of -decays from light to heavy nuclei. Our results are
consistent with experimental data, including the pioneering measurement for
Sn. These theoretical advances are enabled by systematic effective
field theories of the strong and weak interactions combined with powerful
quantum many-body techniques. This work paves the way for systematic
theoretical predictions for fundamental physics problems. These include the
synthesis of heavy elements in neutron star mergers and the search for
neutrino-less double--decay, where an analogous quenching puzzle is a
major source of uncertainty in extracting the neutrino mass scale.Comment: 20 pages, 18 figure
Converged ab initio calculations of heavy nuclei
We propose a novel storage scheme for three-nucleon (3N) interaction matrix
elements relevant for the normal-ordered two-body approximation used
extensively in ab initio calculations of atomic nuclei. This scheme reduces the
required memory by approximately two orders of magnitude, which allows the
generation of 3N interaction matrix elements with the standard truncation of
, well beyond the previous limit of 18. We demonstrate that this
is sufficient to obtain ground-state energies in Sn converged to within
a few MeV with respect to the truncation. In addition, we study the
asymptotic convergence behavior and perform extrapolations to the un-truncated
limit. Finally, we investigate the impact of truncations made when evolving
free-space 3N interactions with the similarity renormalization group. We find
that the contribution of blocks with angular momentum is
dominated by a basis-truncation artifact which vanishes in the large-space
limit, so these computationally expensive components can be neglected. For the
two sets of nuclear interactions employed in this work, the resulting binding
energy of Sn agrees with the experimental value within theoretical
uncertainties. This work enables converged ab initio calculations of heavy
nuclei.Comment: 13 pages, 10 figure
- …