Chiral and U(1)A symmetries in background magnetic fields from lattice QCD
Abstract
We study chiral symmetry and singlet U(1)A symmetry in QCD in a background magnetic field using lattice QCD. We first clarify the neutral-sector symmetry structure in a pure magnetic background, where the unequal electric charges of the light quarks explicitly reduce the non-singlet flavor symmetry. We identify the neutral-pion--sigma susceptibility difference, χπ0-χσ, as the chiral-partner splitting associated with the surviving neutral non-singlet axial symmetry, and the neutral-pion--delta susceptibility difference, χπ0-χδ0, as the singlet U(1)A partner splitting. We also discuss the disconnected contribution to the neutral-pion susceptibility and its continuum constraint. Numerical results are obtained on fixed-scale (2+1)-flavor HISQ ensembles with ml=ms phys/10, corresponding to a pion mass of about 220~ MeV at vanishing magnetic field. We find that the neutral chiral-partner splitting increases with the magnetic field strength eB at low temperature and decreases at sufficiently large eB near the crossover, providing susceptibility-splitting counterparts of magnetic catalysis and inverse magnetic catalysis, respectively. The singlet U(1)A partner splitting shows an analogous low-temperature enhancement and large-field suppression near the crossover, with the suppression setting in at larger eB and remaining milder than in the chiral channel. These results provide a first lattice-QCD study of neutral-sector probes of chiral and singlet U(1)A partner susceptibility splittings in background magnetic fields.
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