Emergent SO(5) Symmetry at the Néel to Valence-Bond-Solid Transition Article Swipe

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Physics Conformal field theory Valence bond theory Square lattice Central charge Conformal symmetry Scaling Quantum mechanics Condensed matter physics Symmetry breaking Phase transition Global symmetry Quantum phase transition Quantum critical point Mathematical physics Spontaneous symmetry breaking Conformal map Ising model Electron Geometry Atomic orbital Mathematics Mathematical analysis

Adam Nahum , Pablo Serna , J. T. Chalker , M. Ortuño , A. M. Somoza ·

YOU? · · 2015 · Open Access · · DOI: https://doi.org/10.1103/physrevlett.115.267203 · OA: W1919904404

We show numerically that the "deconfined" quantum critical point between the Néel antiferromagnet and the columnar valence-bond solid, for a square lattice of spin 1/2, has an emergent SO(5) symmetry. This symmetry allows the Néel vector and the valence-bond solid order parameter to be rotated into each other. It is a remarkable (2+1)-dimensional analogue of the SO(4)=[SU(2)×SU(2)]/Z(2) symmetry that appears in the scaling limit for the spin-1/2 Heisenberg chain. The emergent SO(5) symmetry is strong evidence that the phase transition in the (2+1)-dimensional system is truly continuous, despite the violations of finite-size scaling observed previously in this problem. It also implies surprising relations between correlation functions at the transition. The symmetry enhancement is expected to apply generally to the critical two-component Abelian Higgs model (noncompact CP(1) model). The result indicates that in three dimensions there is an SO(5)-symmetric conformal field theory that has no relevant singlet operators, so is radically different from conventional Wilson-Fisher-type conformal field theories.