Spin Peierls transition of J1-J2 and extended models with ferromagnetic J1.Sublattice dimerization and thermodynamics of zigzag chains in β-TeVO4

Abstract

The spin-1/2 chain with ferromagnetic exchange J1 < 0 between first neighbors and antiferromagnetic J2 > 0 between second neighbors supports two spin-Peierls (SP) instabilities depending on the frustration α = J2/ J1. Instead of chain dimerization with two spins per unit cell, J1-J2 models with α > 0.65 and linear spin-phonon coupling are unconditionally unstable to sublattice dimerization with four spins per unit cell. Unequal J1 to neighbors to the right and left extends the model to gapped (γ > 0) chains with conditional SP transitions at TSP to dimerized sublattices and a weaker specific heat C(T) anomaly. The spin susceptibility (T) and C(T) are obtained in the thermodynamic limit by a combination of exact diagonalization of small systems with α > 0.65 and density matrix renormalization group (DMRG) calculations of systems up to N 100 spins. Both J1-J2 and γ > 0 models account quantitatively for (T) and C(T) in the paramagnetic phase of β-TeVO4 for T > 8 K, but lower T indicates a gapped chain instead of a J1-J2 model as previously thought. The same parameters and TSP = 4.6 K generate a C(T)/T anomaly that reproduces the anomaly at the 4.6 K transition of β-TeVO4, but not the weak (T) signature.