High-density kaonic-proton matter (KPM) composed of Lambda* equiv K-p multiplets and its astrophysical connections

Abstract

We propose and examine a new high-density composite of * K-p = (s u) (uud), which may be called Kaonic Proton Matter (KPM), or simply, * -Matter, where substantial shrinkage of baryonic bound systems originating from the strong attraction of the (KN)I=0 interaction takes place, providing a ground-state neutral baryonic system with a huge energy gap. The mass of an ensemble of (K-p)m, where m, the number of the K-p pair, is larger than m ≈ 10, is predicted to drop down below its corresponding neutron ensemble, (n)m, since the attractive interaction is further increased by the Heitler-London type molecular covalency, as well as by chiral symmetry restoration of the QCD vacuum. Since the seed clusters (K-p, K-pp and K-K-pp) are short-lived, the formation of such a stabilized relic ensemble, (K-p)m, may be conceived during the Big-Bang Quark Gluon Plasma (QGP) period in the early universe before the hadronization and quark-anti-quark annihilation proceed. At the final stage of baryogenesis a substantial amount of primordial (u,d)'s are transferred and captured into KPM, where the anti-quarks find places to survive forever. The expected KPM state may be cold, dense and neutral q q-hybrid ( Quark Gluon Bound (QGB)) states, [s(u u) ud]m, to which the relic of the disappearing anti-quarks plays an essential role as hidden components. The KPM may also be produced during the formation and decay of neutron stars.