Universal properties of frustrated spin systems: 1/N-expansion and renormalization group approaches

Abstract

We consider a quantum two-dimensional O(N)xO(2)/O(N-2)xO(2) nonlinear sigma model for frustrated spin systems and formulate its 1/N-expansion which involves fluctuating scalar and vector fields describing kinematic and dynamic interactions, respectively. The ground state phase diagram of this model is obtained within the 1/N-expansion and 2+ε renormalization group approaches. The temperature dependence of correlation length in the renormalized classical and quantum critical regimes is discussed. In the region of the symmetry broken ground state in<out, in<out (rhoin,out and chiin,out are the in- and out-of-plane spin stiffnesses and susceptibilities), where the mass Mμ of the vector field can be arbitrarily small, physical properties at finite temperatures are universal functions of rhoin,out, chiin,out, and temperature T. For small Mμ these properties show a crossover from low- to high temperature regime at T Mμ. For in>out or in>out finite-temperature properties are universal functions only at sufficiently large Mμ. The high-energy behaviour in the latter regime is similar to the Landau-pole dependence of the physical charge e in quantum electrodynamics, with mass Mμ playing a role of e-1. The application of the results obtained to the triangular-lattice Heisenberg antiferromagnet is considered.