Recurring region for neutron-star observables
ORAL
Abstract
In this letter, we report a new phenomena of recurring regions when relating observables for hybrid
neutron stars and hybrid neutron-star mergers. To describe dense matter within hybrid stars, we
introduce a percolation to vary the size and characteristics of the deconfinement phase transition to
quark matter. Before and after the percolation, we keep the hadronic and quark phases the same,
described by different realistic models for the equation of state of beta-equilibrated, charge-neutral,
zero-temperature matter. When solving spherical and deformed equations for neutron stars in general
relativity, we find that: no matter the size or characteristics of the percolation region, or the order of
the phase transition on either side (hadronic and quark), as long as we minimize the average sound
speed from the beginning of the percolation region to the central density for a given star, we can
produce equations of state that cross through the same, small recurring region within mass-radius and
mass-tidal deformability diagrams. Our findings provide a new way to produce hybrid equations of
state for dense matter that match a given observation of neutron stars or neutron star mergers.
neutron stars and hybrid neutron-star mergers. To describe dense matter within hybrid stars, we
introduce a percolation to vary the size and characteristics of the deconfinement phase transition to
quark matter. Before and after the percolation, we keep the hadronic and quark phases the same,
described by different realistic models for the equation of state of beta-equilibrated, charge-neutral,
zero-temperature matter. When solving spherical and deformed equations for neutron stars in general
relativity, we find that: no matter the size or characteristics of the percolation region, or the order of
the phase transition on either side (hadronic and quark), as long as we minimize the average sound
speed from the beginning of the percolation region to the central density for a given star, we can
produce equations of state that cross through the same, small recurring region within mass-radius and
mass-tidal deformability diagrams. Our findings provide a new way to produce hybrid equations of
state for dense matter that match a given observation of neutron stars or neutron star mergers.
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Publication: Clevinger, A., Lin, Z., Albino, M., et al. 2025. https://arxiv.org/abs/2506.24069<br><br>
Presenters
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Alexander Clevinger
Kent State University
Authors
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Alexander Clevinger
Kent State University
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Veronica Dexheimer
Kent State University
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Peter Hammond
Pennsylvania State University
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Zidu Lin
University of Tennessee
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Milena Albino
University of Coimbra
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Andrew W Steiner
University of Tennessee