https://doi.org/10.1140/epja/i2016-16066-5
Regular Article - Theoretical Physics
Neutron stars interiors: Theory and reality
1
Department of Physics, University of Oxford, OX1 3PU, Oxford, UK
2
Department of Physics and Astronomy, University of Tennessee, 37996, Knoxville, TN, USA
* e-mail: j.stone@physics.ox.ac.uk
Received:
21
August
2015
Revised:
25
January
2016
Accepted:
27
January
2016
Published online:
24
March
2016
There are many fascinating processes in the universe which we observe in more detail thanks to increasingly sophisticated technology. One of the most interesting phenomena is the life cycle of stars, their birth, evolution and death. If the stars are massive enough, they end their lives in a core-collapse supernova explosion, one of the most violent events in the universe. As a result, the densest objects in the universe, neutron stars and/or black holes, are created. The physical basis of these events should be understood in line with observation. Unfortunately, available data do not provide adequate constraints for many theoretical models of dense matter. One of the most open areas of research is the composition of matter in the cores of neutron stars. Unambiguous fingerprints for the appearance and evolution of particular components, such as strange baryons and mesons, with increasing density, have not been identified. In particular, the hadron-quark phase transition remains a subject of intensive research. In this contribution we briefly survey the most promising observational and theoretical directions leading to progress in understanding high density matter in neutron stars. A possible way forward in modeling high-density matter is outlined, exemplified by the quark-meson-coupling model (QMC). This model makes connection between hadronic structure and the underlying quark make-up. It offers a natural explanation for the saturation of nuclear force and treats high-density matter, containing the full baryon octet, in terms of four uniquely defined parameters adjusted to properties of symmetric nuclear matter at saturation.
© SIF, Springer-Verlag Berlin Heidelberg, 2016
