Phases of SU(2) gauge theory with multiple adjoint Higgs fields in 2+1 dimensions

Abstract

A recent work (arXiv:1811.04930) proposed a SU(2) gauge theory for optimal doping criticality in the cuprate superconductors. The theory contains Nh Higgs fields transforming under the adjoint representation of SU(2), with Nh=1 for the electron-doped cuprates, and Nh=4 for the hole-doped cuprates. We investigate the strong-coupling dynamics of this gauge theory, while ignoring the coupling to fermionic excitations. We integrate out the SU(2) gauge field in a strong-coupling expansion, and obtain a lattice action for the Higgs fields alone. We study such a lattice action, with O(Nh) global symmetry, in an analytic large Nh expansion and by Monte Carlo simulations for Nh=4 and find consistent results. We find a confining phase with O(Nh) symmetry preserved (this describes the Fermi liquid phase in the cuprates), and Higgs phases (describing the pseudogap phase of the cuprates) with different patterns of the broken global O(Nh) symmetry. One of the Higgs phases is topologically trivial, implying the absence of any excitations with residual gauge charges. The other Higgs phase has Z2 topological order, with `vison' excitations carrying a Z2 gauge charge. We find consistent regimes of stability for the topological Higgs phase in both our numerical and analytical analyses.