Global baryonic vortices in rotating nuclear matter become energetically viable due to causality-enforced finite size, competing with local vortices under tunable rotation, size, and chemical potential.
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Minimal domain-wall Skyrmions in magnetized QCD are fermions with baryon number one that split from bosonic pairs without energy cost.
Next-to-leading order chiral perturbation theory yields renormalized magnetic masses and decay constants for the meson octet, with neutral pion mass decreasing, neutral kaon mass unchanged, charged meson masses modified identically, and all decay constants increasing monotonically.
citing papers explorer
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Baryonic vortices in rotating nuclear matter
Global baryonic vortices in rotating nuclear matter become energetically viable due to causality-enforced finite size, competing with local vortices under tunable rotation, size, and chemical potential.
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Fermionic domain-wall Skyrmions of QCD in a magnetic field
Minimal domain-wall Skyrmions in magnetized QCD are fermions with baryon number one that split from bosonic pairs without energy cost.
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Meson Octet in a Uniform Magnetic Field
Next-to-leading order chiral perturbation theory yields renormalized magnetic masses and decay constants for the meson octet, with neutral pion mass decreasing, neutral kaon mass unchanged, charged meson masses modified identically, and all decay constants increasing monotonically.