Phases and phase transitions in a dimerized spin-12 XXZ chain

Abstract

We revisit the phase diagram of the dimerized XXZ spin-12 chain with nearest-neighbor couplings which was studied numerically in Phys. Rev. B 106, L201106 (2022). The model has isotropic XY couplings which have a uniform value and ZZ couplings which have a dimerized form, with strengths Ja and Jb on alternate bonds. We find a rich phase diagram in the region of positive Ja, ~Jb. We provide a detailed understanding of the different phases and associated quantum phase transitions using a combination of mean-field theory, low-energy effective Hamiltonians, renormalization group calculations employing the technique of bosonization, and numerical calculations using the density-matrix renormalization group (DMRG) method. The phase diagram consists of two Ising paramagnetic phases called IPM0 and IPMπ, and a phase with Ising Neel order called IN; all these phases are gapped. The phases IPM0 and IPMπ are separated by a gapless phase transition line given by 0 Ja = Jb 1 which is described by a conformal field theory with central charge c=1. There are two gapless phase transition lines separating IPM0 from IN and IPMπ from IN; these are described by conformal field theories with c=12 corresponding to quantum Ising transitions. The c=1 line bifurcates into the two c=12 lines at the point Ja = Jb = 1; the shape of the bifurcation is found analytically using RG calculations. A symmetry analysis shows that IPM0 is a topologically trivial phase while IPMπ is a time-reversal symmetry-protected topological phase (SPT) with spin-12 states at the two ends of an open system. The numerical results obtained by the DMRG method are in good agreement with the analytical results. Finally we propose experimental platforms for testing our results.