Haldane and Dimer phases in a frustrated spin chain: an exact groundstate and associated topological phase transition

Abstract

A Heisenberg spin-s chain with alternating ferromagnetic (-J1F<0) and antiferromagnetic (J1A>0) nearest-neighbor (NN) interactions, exhibits the Dimer and spin-2s Haldane phases in the limits J1F/J1A → 0 and J1F/J1A → ∞ respectively. These two phases are understood to be topologically equivalent. Induction of the frustration through the next nearest-neighbor ferromagnetic interaction (-J2F<0) produces a very rich quantum phase diagram. With frustration, the whole phase diagram is divided into a ferromagnetic (FM) and a nonmagnetic (NM) phase. For s=1/2, the full NM phase is seen to be of Haldane-Dimer type, but for s>1/2, a spiral phase comes between the FM and the Haldane-Dimer phases. The study of a suitably defined string-order parameter and spin-gap at the phase boundary indicates that the Haldane-Dimer and spiral phases have different topological characters. We also find that, along the J2F= 12 J1F line in the NM phase, an NN dimer state is the exact groundstate, provided J1A>JC= J1F where s + h for applied magnetic field h. Without magnetic field, the position of JC is on the FM-NM phase boundary when s=1/2, but for s>1/2, the location of JC is on the phase separation line between the Haldane-Dimer and spiral phases.