Fractionalization of flux tubes in 3d and screening by emergent electric charges in 2d (2412.14532v1)
Abstract: We consider a class of 3d theories with a $\mathbb Z_n$ magnetic symmetry in which confinement is generated by charge $n$ clusters of monopoles. Such theories naturally arise in quantum antiferromagnets in 2+1, QCD-like theories on $\mathbb R3 \times S1$, and $U(1)$ lattice theory with restricted monopole sums. A confining string fractionates into $n$ strings which each carry $1/n$ electric flux. We construct a twisted compactification (equivalently periodic compactification with a topological defect insertion) on $\mathbb R2 \times S1$ that preserves the vacuum structure. Despite the absence of electric degrees of freedom in the microscopic Lagrangian, we show that large Wilson loops are completely/partially screened for even/odd $n$, even when the compactification scale is much larger than the Debye length. We show the emergence of fractional electric charges $(\pm 2/n)$ at the junctions of the domain lines and topological defects. We end with some remarks on screening vs. confinement.