Quark condensates and magnetization in chiral perturbation theory in a uniform magnetic field

Abstract

We reconsider the problem of calculating the vacuum free energy (density) of QCD and the shift of the quark condensates in the presence of a uniform background magnetic field using two-and-three-flavor chiral perturbation theory (). Using the free energy, we calculate the degenerate, light quark condensates in the two-flavor case and the up, down and strange quark condensates in the three-flavor case. We also use the vacuum free energy to calculate the (renormalized) magnetization of the QCD vacuum, which shows that it is paramagnetic. We find that the three-flavor light-quark condensates and (renormalized) magnetization are improvements on the two-flavor results. We also find that the average light quark condensate is in agreement with the lattice up to eB=0.2 \ GeV2, and the (renormalized) magnetization is in agreement up to eB=0.3 \ GeV2, while three-flavor , which gives a non-zero shift in the difference between the light quark condensates unlike two-flavor , underestimates the difference compared to lattice QCD.