The 34th annual “International Symposium on Lattice Field Theory” will bring together a global community of researchers from theoretical particle physics and quantum field theory, who employ theoretical, numerical and computational methods to study the properties of strongly interacting physical systems – above all Quantum Chromodynamics (QCD), the theory which describes the interactions of quarks and gluons and how they bind together to form the particles we see in experiments. The Symposium is returning to the UK for the first time since 1997, when it took place in Edinburgh, and has never before been held in England.
The dual superconductivity is a promising mechanism for quark confinement. We have presented a new formulation of the Yang-Mills theory on the lattice, that enables us to change the original non-Abelian gauge field into the new field variables such that one of them called the restricted field gives the dominant contribution to quark confinement in the gauge-independent way. We have pointed out that the $SU(3)$ Yang-Mills theory has a new way of reformulation using new field variables (minimal option), in addition to the conventional option adopted by Cho, Faddeev and Niemi (maximal option). In the preceding lattice conferences, we have accumulated the numerical evidences that support the non-Abelian dual superconductivity using the minimal option for the SU(3) Yang-Mills theory. This should be compared with Abelian dual superconductivity from the maximal option which is a gauge invariant version of the conventional Abelian projection method in the maximal Abelian gauge. In this talk, We focus on discriminating between two reformulations, i.e., maximal and minimal options of $SU(3)$ Yang-Mills theory for quark confinement from the viewpoint of dual superconductivity. We investigate the dual Meissner effect at finite temperature and the phase transition in both options which are compared with the original Yang-Mills theory. For this purpose, we measure the distribution of the chromoelectric flux connecting a quark and an antiquark and the induced magnetic-monopole current around the flux tube in both confinement/deconfinement phase.