Pseudoscalar condensation induced by chiral anomaly and vorticity for massive fermions

Abstract: We derive the pseudoscalar condensate induced by anomaly and vorticity from the Wigner function for massive fermions in homogeneous electromagnetic fields. It has an anomaly term and a forcevorticity coupling term. As a mass effect, the pseudoscalar condensate is linearly proportional to the fermion mass in small mass expansion. By a generalization to two-flavor and three-flavor cases, the neutral pion and eta meson condensates are calculated from the Wigner function and have anomaly parts as well as force-vor… Show more

“…The 4×4 matrices ± in Eqs. (30) and (31) are defined as products of the relativistic Boltzmann distributions (Jüttner distributions [60]) and matrices ± , namely…”

“…In the present work, by discussing the quantum kinetic equation in the semi-classical expansion and by developing the hydrodynamic framework with a classical treatment of spin, we eventually conclude on the applicability range of Eqs. (30) and (31). Nonetheless, before concluding on this issue, we develop a formalism based on Eqs.…”

“…Nonetheless, before concluding on this issue, we develop a formalism based on Eqs. (30) and (31), as this allows us to build a necessary theoretical scheme and to introduce relevant definitions and concepts.…”

“…Theoretical studies analyzing the spin polarization and vorticity formation in heavy-ion collisions include several highly debated topics: the importance of the spin-orbit coupling [22,23], global equilibrium with a rigid rotation [24,25,26,27], kinetic models of spin dynamics [28,29,30,31], anomalous hydrodynamics [32,33], the Lagrangian formulation of hydrodynamics [34,35,36,37] and hydrodynamic treatment of the spin tensor using holographic techniques [38].…”

Relativistic hydrodynamics for spin-polarized fluids

“…The 4×4 matrices ± in Eqs. (30) and (31) are defined as products of the relativistic Boltzmann distributions (Jüttner distributions [60]) and matrices ± , namely…”

“…In the present work, by discussing the quantum kinetic equation in the semi-classical expansion and by developing the hydrodynamic framework with a classical treatment of spin, we eventually conclude on the applicability range of Eqs. (30) and (31). Nonetheless, before concluding on this issue, we develop a formalism based on Eqs.…”

“…Nonetheless, before concluding on this issue, we develop a formalism based on Eqs. (30) and (31), as this allows us to build a necessary theoretical scheme and to introduce relevant definitions and concepts.…”

“…Theoretical studies analyzing the spin polarization and vorticity formation in heavy-ion collisions include several highly debated topics: the importance of the spin-orbit coupling [22,23], global equilibrium with a rigid rotation [24,25,26,27], kinetic models of spin dynamics [28,29,30,31], anomalous hydrodynamics [32,33], the Lagrangian formulation of hydrodynamics [34,35,36,37] and hydrodynamic treatment of the spin tensor using holographic techniques [38].…”

Relativistic hydrodynamics for spin-polarized fluids

“…Recent measurements of the Λ-hyperon spin polarization in heavy-ion collisions by the STAR experiment [1,2] have inspired a broad interest in the theoretical studies related to spin polarization and vorticity formation. The results of various investigations that refer to: the spin-orbit coupling [3,4,5,6,7], statistical properties of matter in global equilibrium [8,9,10,11,12,13], kinetic models of spin dynamics [14,15,16,17], hydrodynamics with triangle anomalies [18,19] and the Lagrangian formulation of hydrodynamics [20,21,22] have been reported in this context.…”

Wigner function approach to polarization-vorticity coupling and hydrodynamics with spin

Recent developments in chiral and spin polarization effects in heavy-ion collisions