PAIRING AND BOUND STATES IN NUCLEAR MATTER

AbstractPhases of nuclear matter are crucial in the determination of physical properties of neutron stars (NS). In the core of NS, the density and pressure become so large that the nuclear matter possibly undergoes phase transition into a deconfined phase, consisting of quarks and gluons and their colour bound states. Even though the quark-gluon plasma has been observed in ultra-relativistic heavy-ion collisions (Gyulassy and McLerran, Nucl Phys A 750:30–63, 2005; Andronic et al., Nature 561: 321–330, 2018), it is still unclear whether exotic quark matter exists inside neutron stars. Recent results from the combination of various perturbative theoretical calculations with astronomical observations (Demorest et al., Nature 467:1081–1083, 2010; Antoniadis et al., Science 340:1233232, 2013) shows that (exotic) quark matter could exist inside the cores of neutron stars above 2.0 solar masses ($$M_{\odot }$$ M ⊙ ) (Annala et al., Nat Phys, 10.1038/s41567-020-0914-9, arXiv:1903.09121 [astro-ph.HE], 2020). We revisit the holographic model in Refs. (Burikham et al., JHEP 05:006, arXiv:0811.0243 [hep-ph], 2009; Burikham et al., JHEP 06:040, arXiv:1003.5470 [hep-ph], 2010) and implement the equation of states (EoS) of multiquark nuclear matter to interpolate the pQCD EoS in the high-density region with the nuclear EoS known at low densities. For sufficiently large energy density scale ($$\epsilon _{s}$$ ϵ s ) of the model, it is found that multiquark phase is thermodynamically prefered than the stiff nuclear matter above the transition points. The NS with holographic multiquark core could have masses in the range $$1.96{-}2.23~(1.64{-}2.10) M_{\odot }$$ 1.96 - 2.23 ( 1.64 - 2.10 ) M ⊙ and radii $$14.3{-}11.8~(14.0{-}11.1)$$ 14.3 - 11.8 ( 14.0 - 11.1 ) km for $$\epsilon _{s}=26~(28)$$ ϵ s = 26 ( 28 ) GeV/fm$$^{3}$$ 3 respectively. Effects of proton–baryon fractions are studied for certain type of baryonic EoS; larger proton fractions could reduce radius of the NS with multiquark core by less than a kilometer.

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PIONIC ATOMS PROBING πNN RESONANCES

International Journal of Modern Physics A ◽

10.1142/s0217751x05021166 ◽

2005 ◽

Vol 20 (24) ◽

pp. 5657-5661

Author(s):

M. I. KRIVORUCHENKO ◽

B. V. MARTEMYANOV ◽

AMAND FAESSLER ◽

C. FUCHS

Keyword(s):

Nuclear Matter ◽

Bound States ◽

Optical Potential ◽

Energy Levels ◽

Matter Density ◽

X Ray ◽

Nuclear Matter Density ◽

Dibaryon Resonance ◽

Pionic Atoms

The pion optical potential generated by the hypothetical πNN-coupled NN-decoupled dibaryon resonance d′(2065) is calculated to the lowest order in nuclear matter density. The contribution to the pion optical potential is found to be within the empirical errors, so the d′(2065) existence currently does not contradict to the observed properties of the π--nucleus bound states. Future progress in the pionic X-ray spectroscopy can reveal contributions of πNN resonances to energy levels and widths of the pionic atoms.

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Can strangelets be detected in a large LAr neutrino detector?

Journal of Cosmology and Astroparticle Physics ◽

10.1088/1475-7516/2021/11/040 ◽

2021 ◽

Vol 2021 (11) ◽

pp. 040

Author(s):

Mihaela Pârvu ◽

Ionel Lazanu

Keyword(s):

Neutrino Physics ◽

Nuclear Matter ◽

Bound States ◽

Liquid Argon ◽

Neutrino Detector ◽

Strange Quarks ◽

Intermediate Energies ◽

The Future

Abstract Predicted as possible bound states of up, down and strange quarks, strangelets could be more energetically favourable and more stable than nuclear matter. In this paper we explore the possibility of detecting such particles with the future large liquid argon detectors developed for neutrino physics. Using signals from ionization and scintillation, as well as measuring the range, we suggest that a calorimetric TPC detector is able to put in evidence and to discriminate between light strangelets and normal isotopes at intermediate energies.

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Recent Radiative and Collisional Atomic Data of Astrophysical Interest

International Astronomical Union Colloquium ◽

10.1017/s0252921100107596 ◽

1988 ◽

Vol 102 ◽

pp. 129-132

Author(s):

K.L. Baluja ◽

K. Butler ◽

J. Le Bourlot ◽

C.J. Zeippen

Keyword(s):

Mass Production ◽

Bound States ◽

Physical Models ◽

Impact Excitation ◽

Electron Impact Excitation ◽

Atomic Data ◽

Isoelectronic Sequence ◽

Astrophysical Interest ◽

Radiative Transitions ◽

Forbidden Transitions

SummaryUsing sophisticated computer programs and elaborate physical models, accurate radiative and collisional atomic data of astrophysical interest have been or are being calculated. The cases treated include radiative transitions between bound states in the 2p4and 2s2p5configurations of many ions in the oxygen isoelectronic sequence, the photoionisation of the ground state of neutral iron, the electron impact excitation of the fine-structure forbidden transitions within the 3p3ground configuration of CℓIII, Ar IV and K V, and the mass-production of radiative data for ions in the oxygen and fluorine isoelectronic sequences, as part of the international Opacity Project.

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