Author(s)

Ahmad A. Hujeirat^*, Mauritz M. Wicker

IWR, University of Heidelberg, Heidelberg, Germany.

Exploring the state of ultra-cold supranuclear dense matter that makes up the cores of massive neutron stars is one of the greatest unresolved problems in modern physics. In this letter, we show that when the interiors of pulsars are made of compressible and dissipative normal matter, the commonly used solution procedures combined with the known EOSs yield widely scattered solutions and poorly determined radii. A remarkable agreement emerges, however, if pulsars harbour cores that are made of incompressible entropy-free superfluids (SuSu-matter) embedded in flat spacetimes. Such supranuclear dense matter should condensate to form false vacua as predicated by non-perterbative QCD vacuum. The solutions here are found to be physically consistent and mathematically elegant, irrespective of the object’s mass. Based thereon, we conclude that the true masses of massive NSs may differ significantly from those revealed by direct observation.

General Relativity, Pulsars, Neutron Stars, EOSs, QCD, Incompressibility, Superfluidity, Super-Conductivity

Hujeirat, A. and Wicker, M. (2023) The EOSs and the Blatant Discrepancy in Modelling Massive Neutron Stars: Origin and a Possible Solution Method. Journal of Modern Physics, 14, 1458-1463. doi: 10.4236/jmp.2023.1411085.