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Magnetic catalysis and the chiral condensate in holographic QCD

Alfonso Ballon-Bayona, Jonathan P. Shock, Dimitrios Zoakos

2020Journal of High Energy Physics29 citationsDOIOpen Access PDF

Abstract

A bstract We investigate the effect of a non-zero magnetic field on the chiral condensate using a holographic QCD approach. We extend the model proposed by Iatrakis, Kiritsis and Paredes in [1] that realises chiral symmetry breaking dynamically from 5d tachyon condensation. We calculate the chiral condensate, magnetisation and susceptibilities for the confined and deconfined phases. The model leads, in the probe approximation, to magnetic catalysis of chiral symmetry breaking in both confined and deconfined phases. In the chiral limit, m q = 0, we find that in the deconfined phase a sufficiently strong magnetic field leads to a second order phase transition from the chirally restored phase to a chirally broken phase. The transition becomes a crossover as the quark mass increases. Due to a scaling in the temperature, the chiral transition will also be interpreted as a transition in the temperature for fixed magnetic field. We elaborate on the relationship between the chiral condensate, magnetisation and the (magnetic) free energy density. We compare our results at low and moderate temperatures with lattice QCD results.

Topics & Concepts

PhysicsChiral symmetry breakingTachyon condensationQuantum chromodynamicsCondensed matter physicsPhase transitionDeconfinementMagnetizationChiral anomalySymmetry breakingCritical phenomenaChiral perturbation theoryMagnetic fieldParticle physicsQuantum mechanicsString (physics)String field theoryBlack Holes and Theoretical PhysicsQuantum Chromodynamics and Particle InteractionsParticle physics theoretical and experimental studies
Magnetic catalysis and the chiral condensate in holographic QCD | Litcius