Tamás Kovács scite author profile

We study the physical mechanism of how an external magnetic field influences the QCD quark condensate. Two competing mechanisms are identified, both relying on the interaction between the magnetic field and the low quark modes. While the coupling to valence quarks enhances the condensate, the interaction with sea quarks suppresses it in the transition region. The latter `sea effect' acts by ordering the Polyakov loop and, thereby, reduces the number of small Dirac eigenmodes and the condensate. It is most effective around the transition temperature, where the Polyakov loop effective potential is flat and a small correction to it by the magnetic field can have a significant effect. Around the critical temperature, the sea suppression overwhelms the valence enhancement, resulting in a net suppression of the condensate, named inverse magnetic catalysis. We support this physical picture by lattice simulations including continuum extrapolated results on the Polyakov loop as a function of temperature and magnetic field. We argue that taking into account the increase in the Polyakov loop and its interaction with the low-lying modes is essential to obtain the full physical picture, and should be incorporated in effective models for the description of QCD in magnetic fields in the transition region.Comment: 19 pages, 8 figures, new reference added, version accepted for publicatio

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Pentaquark hadrons from lattice QCD

Csikor¹,

Fodor²,

Katz³

et al. 2003

J. High Energy Phys.

156

187

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We study spin 1/2 isoscalar and isovector candidates in both parity channels for the recently discovered Θ + (1540) pentaquark particle in quenched lattice QCD. Our analysis takes into account all possible uncertainties, such as statistical, finite size and quenching errors when performing the chiral and continuum extrapolations and we have indications that our signal is separated from scattering states. The lowest mass that we find in the I P = 0 − channel is in complete agreement with the experimental value of the Θ + mass. On the other hand, the lowest mass state in the opposite parity I P = 0 + channel is much higher. Our findings suggests that the parity of the Θ + is negative.

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Coarsening dynamics of theXYmodel

et al. 1993

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Tamás Kovács

Calculation of the axion mass based on high-temperature lattice quantum chromodynamics

Inverse magnetic catalysis and the Polyakov loop

Pentaquark hadrons from lattice QCD

Coarsening dynamics of theXYmodel

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