Bond-order wave phase, spin solitons and thermodynamics of a frustrated linear spin-1/2 Heisenberg antiferromagnet

Abstract

The linear spin-1/2 Heisenberg antiferromagnet with exchanges J1, J2 between first and second neighbors has a bond-order wave (BOW) phase that starts at the fluid-dimer transition at J2/J1 = 0.2411 and is particularly simple at J2/J1 = 1/2. The BOW phase has a doubly degenerate singlet ground state, broken inversion symmetry and a finite energy gap Em to the lowest triplet state. The interval 0.4<J2/J1<1.0 has large Em and small finite size corrections. Exact solutions are presented up to N=28 spins with either periodic or open boundary conditions and for thermodynamics up to N=18. The elementary excitations of the BOW phase with large Em are topological spin-1/2 solitons that separate BOWs with opposite phase in a regular array of spins. The molar spin susceptibility M(T) is exponentially small for T Em and increases nearly linearly with T to a broad maximum. J1, J2 spin chains approximate the magnetic properties of the BOW phase of Hubbard-type models and provide a starting point for modeling alkali-TCNQ salts.