Abstract
We study an ’t Hooft anomaly of massless QCD at finite temperature. With the imaginary baryon chemical potential at the Roberge-Weiss point, there is a ℤ2 symmetry which can be used to define confinement. We show the existence of a mixed anomaly between the ℤ2 symmetry and the chiral symmetry, which gives a strong relation between confinement and chiral symmetry breaking. The anomaly is a parity anomaly in the QCD Lagrangian reduced to three dimensions. It is reproduced in the chiral Lagrangian by a topological term related to Skyrmion charge, matching the anomaly before and after QCD phase transition. The effect of the imaginary chemical potential is suppresssed in the large N expansion, and we discuss implications of the ’t Hooft anomaly matching for the nature of QCD phase transition with and without the imaginary chemical potential. Arguments based on universality alone are disfavored, and a first order phase transition may be the simplest possibility if the large N expansion is qualitatively good.
Highlights
Anomaly of QCD LagrangianWe consider the standard QCD-like theories with general color and flavor numbers Nc and Nf
Because of difficulties of numerical lattice simulation in small quark mass region, it is important to study the overall picture rather than just specific quark masses, and perform consistency checks to really firmly establish such results
We show the existence of a mixed anomaly between the Z2 symmetry and the chiral symmetry, which gives a strong relation between confinement and chiral symmetry breaking
Summary
We consider the standard QCD-like theories with general color and flavor numbers Nc and Nf. Including the gauge as well as some of the global symmetry groups, the quark fields are acted by. SU(Nf )L and SU(Nf )R are the standard chiral symmetry They act on the left and right handed quarks ψL Which acts trivially on the quark fields Ψ. More explicitly it is generated by elements c1, c2 ∈ D given by c1 = e2πi/Nc , 1, 1, e−2πi/Nc ,. In terms of U(1)B rather than U(1)V , it is given by c2 = e2πi/Nf , e2πi/Nf , e−2πiNc/Nf ∈ SU(Nf )L × SU(Nf )R × U(1)B. This c2 acts trivially on all gauge invariant operators
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