Lattice simulations find spatially inhomogeneous confinement-deconfinement transition in weakly accelerated SU(3) gluodynamics, with phase boundary following TE prediction and unchanged critical temperature.
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Lattice simulations in Rindler spacetime show that acceleration turns the confinement-deconfinement transition in gluodynamics into a spatial crossover that approximately follows the Tolman-Ehrenfest law, while the critical temperature stays unchanged.
The Weyl anomaly induces a new non-dissipative current in accelerated fluids that fixes the electromagnetic-acceleration coupling at second order in hydrodynamics.
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Spatially inhomogeneous confinement-deconfinement phase transition in accelerated gluodynamics
Lattice simulations find spatially inhomogeneous confinement-deconfinement transition in weakly accelerated SU(3) gluodynamics, with phase boundary following TE prediction and unchanged critical temperature.
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Spatial confinement-deconfinement transition in accelerated gluodynamics within lattice simulation
Lattice simulations in Rindler spacetime show that acceleration turns the confinement-deconfinement transition in gluodynamics into a spatial crossover that approximately follows the Tolman-Ehrenfest law, while the critical temperature stays unchanged.
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Weyl anomaly induced transport in hydrodynamics
The Weyl anomaly induces a new non-dissipative current in accelerated fluids that fixes the electromagnetic-acceleration coupling at second order in hydrodynamics.