S = 1 pyrochlore magnets with competing anisotropies: A tale of two Coulomb phases, Z2 flux confinement and XY-like transitions
Abstract
We argue that the low-temperature physics of S=1 pyrochlore magnets with a predominantly Ising-like easy-axis exchange coupling J that favors the local tetrahedral body diagonals, and a comparably large easy-plane single-ion anisotropy =J + μ (|μ| J) that favors the plane perpendicular to these local axes will exhibit interesting new phenomena due to the competition between J and . In the T/J → 0 limit, we find three low temperature phases as a function of μ/T: a short-range correlated paramagnetic phase, and two topologically-distinct Coulomb liquids separated by a Z2 flux confinement transition. Both Coulomb liquids are described at long-wavelengths by a fluctuating divergence-free polarization field and have characteristic pinch-point singularities in their structure factor. In one Coulomb phase, the flux of this polarization field is confined to even integers, while it takes on all integer values in the other Coulomb phase. Experimental realizations with |μ| J and negative are predicted to exhibit signatures of a transition from a flux-deconfined Coulomb phase to the flux-confined Coulomb phase as they are cooled below Tc2 ≈ 1.57|μ|, while realizations with positive μ J will show signatures of a transition from a flux-deconfined Coulomb liquid to a short-range correlated paramagnet via a continuous XY-like transition at Tc1 ≈ 0.98 μ.
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