Electric and magnetic screening masses at finite temperature from generalized Polyakov-line correlations in two-flavor lattice QCD
Y Maezawa, S Aoki, S Ejiri, T Hatsuda, N Ishii… - Physical Review D …, 2010 - APS
Y Maezawa, S Aoki, S Ejiri, T Hatsuda, N Ishii, K Kanaya, N Ukita, T Umeda…
Physical Review D—Particles, Fields, Gravitation, and Cosmology, 2010•APSScreenings of the quark-gluon plasma in electric and magnetic sectors are studied on the
basis of generalized Polyakov-line correlation functions in lattice QCD simulations with two
flavors of improved Wilson quarks. Using the Euclidean-time reflection (R) and the charge
conjugation (C), electric and magnetic screening masses are extracted in a gauge-invariant
manner. Long distance behavior of the standard Polyakov-line correlation in the quark-gluon
plasma is found to be dictated by the magnetic screening. Also, the ratio of the two screening …
basis of generalized Polyakov-line correlation functions in lattice QCD simulations with two
flavors of improved Wilson quarks. Using the Euclidean-time reflection (R) and the charge
conjugation (C), electric and magnetic screening masses are extracted in a gauge-invariant
manner. Long distance behavior of the standard Polyakov-line correlation in the quark-gluon
plasma is found to be dictated by the magnetic screening. Also, the ratio of the two screening …
Screenings of the quark-gluon plasma in electric and magnetic sectors are studied on the basis of generalized Polyakov-line correlation functions in lattice QCD simulations with two flavors of improved Wilson quarks. Using the Euclidean-time reflection () and the charge conjugation (), electric and magnetic screening masses are extracted in a gauge-invariant manner. Long distance behavior of the standard Polyakov-line correlation in the quark-gluon plasma is found to be dictated by the magnetic screening. Also, the ratio of the two screening masses agrees with that obtained from the dimensionally-reduced effective field theory and the supersymmetric Yang-Mills theory.
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