12,756 research outputs found
Links Between Heavy Ion and Astrophysics
Heavy ion experiments provide important data to test astrophysical models.
The high density equation of state can be probed in HI collisions and applied
to the hot protoneutron star formed in core collapse supernovae. The Parity
Radius Experiment (PREX) aims to accurately measure the neutron radius of
Pb with parity violating electron scattering. This determines the
pressure of neutron rich matter and the density dependence of the symmetry
energy. Competition between nuclear attraction and coulomb repulsion can form
exotic shapes called nuclear pasta in neutron star crusts and supernovae. This
competition can be probed with multifragmentation HI reactions. We use large
scale semiclassical simulations to study nonuniform neutron rich matter in
supernovae. We find that the coulomb interactions in astrophysical systems
suppress density fluctuations. As a result, there is no first order liquid
vapor phase transition. Finally, the virial expansion for low density matter
shows that the nuclear vapor phase is complex with significant concentrations
of alpha particles and other light nuclei in addition to free nucleons.Comment: 8 pages, 6 figures. To be published in "Dynamics and Thermodynamics
with Nucleon Degrees of Freedom", eds. P. Chomaz, F. Gulminelli, J. Natowitz,
and S. Yennello, http://cyclotron.tamu.edu/wci3/wci_book.htm
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Artificial Intelligence, International Competition, and the Balance of Power (May 2018)
World leaders, CEOs, and academics have suggested that a revolution in artificial intelligence is upon us. Are they right, and what will advances in artificial intelligence mean for international competition and the balance of power? This article evaluates how developments in artificial intelligence (AI) — advanced, narrow applications in particular — are poised to influence military power and international politics. It describes how AI more closely resembles “enabling” technologies such as the combustion engine or electricity than a specific weapon. AI’s still-emerging developments make it harder to assess than many technological changes, especially since many of the organizational decisions about the adoption and uses of new technology that generally shape the impact of that technology are in their infancy. The article then explores the possibility that key drivers of AI development in the private sector could cause the rapid diffusion of military applications of AI, limiting first-mover advantages for innovators. Alternatively, given uncertainty about the technological trajectory of AI, it is also possible that military uses of AI will be harder to develop based on private-sector AI technologies than many expect, generating more potential first-mover advantages for existing powers such as China and the United States, as well as larger consequences for relative power if a country fails to adapt. Finally, the article discusses the extent to which U.S. military rhetoric about the importance of AI matches the reality of U.S. investments.LBJ School of Public Affair
Neutron rich nuclei and neutron stars
The PREX experiment at Jefferson Laboratory measures the neutron radius of
208Pb with parity violating electron scattering in a way that is free from most
strong interaction uncertainties. The 208Pb radius has important implications
for neutron rich matter and the structure of neutron stars. We present first
PREX results, describe future plans, and discuss a follow on measurement of the
neutron radius of 48Ca. We review radio and X-ray observations of neutron star
masses and radii. These constrain the equation of state (pressure versus
density) of neutron rich matter. We present a new energy functional that is
simultaneously fit to both nuclear and neutron star properties. In this
approach, neutron star masses and radii constrain the energy of neutron matter.
This avoids having to rely on model dependent microscopic calculations of
neutron matter. The functional is then used to predict the location of the drip
lines and the properties of very neutron rich heavy nuclei.Comment: 8 pages, 4 figures, proceedings of International Conference on
Fission and Neutron Rich Nuclei 5, Sanibel, F
Multi-messenger observations of neutron rich matter
Neutron rich matter is central to many fundamental questions in nuclear
physics and astrophysics. Moreover, this material is being studied with an
extraordinary variety of new tools such as the Facility for Rare Isotope Beams
(FRIB) and the Laser Interferometer Gravitational Wave Observatory (LIGO). We
describe the Lead Radius Experiment (PREX) that uses parity violating electron
scattering to measure the neutron radius in Pb. This has important
implications for neutron stars and their crusts. We discuss X-ray observations
of neutron star radii. These also have important implications for neutron rich
matter. Gravitational waves (GW) open a new window on neutron rich matter. They
come from sources such as neutron star mergers, rotating neutron star
mountains, and collective r-mode oscillations. Using large scale molecular
dynamics simulations, we find neutron star crust to be very strong. It can
support mountains on rotating neutron stars large enough to generate detectable
gravitational waves. Finally, neutrinos from core collapse supernovae (SN)
provide another, qualitatively different probe of neutron rich matter.
Neutrinos escape from the surface of last scattering known as the
neutrino-sphere. This is a low density warm gas of neutron rich matter.
Observations of neutrinos can probe nucleosyntheses in SN. Simulations of SN
depend on the equation of state (EOS) of neutron rich matter. We discuss a new
EOS based on virial and relativistic mean field calculations. We believe that
combing astronomical observations using photos, GW, and neutrinos, with
laboratory experiments on nuclei, heavy ion collisions, and radioactive beams
will fundamentally advance our knowledge of compact objects in the heavens, the
dense phases of QCD, the origin of the elements, and of neutron rich matter.Comment: 13 pages, 4 figures, Added discussion of dipole polarizability, pygmy
resonances, and neutron skin
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