Spin nematic phase in (quasi-)one-dimensional frustrated magnet in strong magnetic field

Abstract

We discuss spin-1/2 one-dimensional (1D) and quasi-1D magnets with competing ferromagnetic nearest-neighbor J1 and antiferromagnetic next-nearest-neighbor J exchange interactions in strong magnetic field H. It is well known that due to attraction between magnons quantum phase transitions (QPTs) take place at H=Hs from the fully polarized phase to nematic ones if J>|J1|/4. Such a transition at J>0.368|J1| is characterized by softening of the two-magnon bound-state spectrum. Using a bond operator formalism we propose a bosonic representation of the spin Hamiltonian containing, aside from bosons describing one-magnon spin-1 excitations, a boson describing spin-2 excitations which spectrum coincides at H Hs with the two-magnon bound-state spectrum obtained before. The presence of the bosonic mode in the theory that softens at H=Hs makes substantially standard the QPT consideration. In 1D case at H<Hs, we find an expression for the magnetization which describes well existing numerical data. Expressions for spin correlators are obtained which coincide with those derived before either in the limiting case of J|J1| or using a phenomenological theory. In quasi-1D magnets, we find that the boundary in the H--T plane between the fully polarized and the nematic phases is given by Hs(0)-Hs(T) T3/2. Simple expressions are obtained in the nematic phase for static spin correlators, spectra of magnons and the soft mode, magnetization and the nematic order parameter. All static two-spin correlation functions are short ranged with the correlation length proportional to 1/(1+|J1|/J). Dynamical spin susceptibilities are discussed and it is shown that the soft mode can be observed experimentally in the longitudinal channel.