Quark confinement due to unified magnetic monopoles and vortices reduced from symmetric instantons with holography

Abstract

We develop a geometric framework to analyze quark confinement in four-dimensional Euclidean SU(2) Yang--Mills theory in terms of finite-action topological defects. Starting from self-dual Yang--Mills configurations, we restrict to symmetric instantons with spatial rotation symmetry so that dimensional reduction preserves conformal equivalence. This requirement maps R4 to curved backgrounds with compact directions and, in particular, identifies the reduced configurations with (i) hyperbolic magnetic monopoles of Atiyah type on H3 AdS3 (from an SO(2) S1 symmetry) and (ii) hyperbolic vortices of Witten--Manton type on H2 AdS2 (from an SO(3) SU(2) symmetry). We provide an explicit field map relating the monopole and vortex variables, enabling a unified treatment of these defects within the original four-dimensional setting. Moreover, the hyperbolic monopole on H3 is completely determined by its holographic data on the conformal boundary S2∞, which reduces a non-Abelian Wilson loop placed on ∂ H3 to an Abelian loop determined by the vortex U(1) field (Abelian dominance and monopole dominance), without further dynamical assumptions beyond the symmetry reduction. In the semiclassical dilute-gas regime of these finite-action defects, the framework yields the Wilson area law, thereby providing analytic support for the dual-superconductor picture of confinement.