Litcius/Paper detail

Covariant Density Functional Theory in Nuclear Physics and Astrophysics

Junjie Yang, J. Piekarewicz

2020Annual Review of Nuclear and Particle Science38 citationsDOIOpen Access PDF

Abstract

How does subatomic matter organize itself? Neutron stars are cosmic laboratories uniquely poised to answer this fundamental question that lies at the heart of nuclear science. Newly commissioned rare isotope facilities, telescopes operating across the entire electromagnetic spectrum, and ever more sensitive gravitational wave detectors will probe the properties of neutron-rich matter with unprecedented precision over an enormous range of densities. A coordinated effort between observation, experiment, and theoretical research is of paramount importance for realizing the full potential of these investments. Theoretical nuclear physics provides valuable insights into the properties of neutron-rich matter in regimes that are not presently accessible to experiment or observation. In particular, nuclear density functional theory is likely the only tractable framework that can bridge the entire nuclear landscape by connecting finite nuclei to neutron stars. This compelling connection is the main scope of the present review.

Topics & Concepts

PhysicsNuclear matterNuclear astrophysicsNeutron starNeutronCovariant transformationNuclear physicsSubatomic particleRange (aeronautics)Particle physicsTheoretical physicsCosmic rayGravitationPhysics beyond the Standard ModelCOSMIC cancer databaseScope (computer science)Nuclear forceAtomic nucleusGravitational waveNuclear structureNuclear densityDark matterNuclear reactionPulsars and Gravitational Waves ResearchNuclear physics research studiesQuantum Chromodynamics and Particle Interactions