First-order phase transitions in spinor Bose gases and frustrated magnets

Abstract

We show that phase transitions in spin-one Bose gases and stacked triangular Heisenberg antiferromagnets -- an example of frustrated magnets with competing interactions -- are described by the same Landau-Ginzburg-Wilson Hamiltonian with O(3)×O(2) symmetry. In agreement with previous nonperturbative-renormalization-group studies of the three-dimensional O(3)×O(2) model, we find that the transition from the normal phase to the superfluid ferromagnetic phase in a spin-one Bose gas is weakly first order and shows pseudoscaling behavior. The (nonuniversal) pseudoscaling exponent is fully determined by the scattering lengths a0 and a2. We provide estimates of in 87Rb, 41K and 7Li atom gases which can be tested experimentally. We argue that pseudoscaling comes from either a crossover phenomena due to proximity of the O(6) Wilson-Fisher fixed point (87Rb and 41K) or the existence of two unphysical fixed points (with complex coordinates) which slow down the RG flow (7Li). These unphysical fixed points are a remnant of the chiral and antichiral fixed points that exist in the O(N)×O(2) model when N is larger than Nc 5.3 (the transition being then second order and controlled by the chiral fixed point). Finally, we discuss a O(2)×O(2) lattice model and show that our results, even though we find the transition to be first order, are compatible with Monte Carlo simulations yielding an apparent second-order transition.