Competing quantum effects in spin crossover chains: spin-orbit coupling, magnetic exchange, and elastic interactions

TL;DR

This paper models spin crossover chains considering elastic, magnetic, and spin-orbit interactions, revealing six phases including topological, disordered, and ferroelastic states through advanced calculations.

Contribution

It introduces a comprehensive model for spin crossover materials that captures competing interactions and predicts multiple novel phases and phase transitions.

Findings

Identification of six distinct phases in the model.

Discovery of a symmetry protected topological Haldane phase.

Observation of a quantum phase transition analogous to the transverse field Ising model.

Abstract

We derive and study a model of square planar, d8 spin crossover materials that treats elastic, magnetic and spin-orbit interactions on an equal footing. For 1D chains density matrix renormalization group calculations show that the competition between these interactions leads to six different phases. For weak spin-orbit coupling (SOC) and large antiferromagnetic interactions we find a symmetry protected topological (SPT) Haldane phase. This is equivalent to the Haldane-large-D phase transition driven by single ion anisotropy(D) in the spin-one Heisenberg model. For strong SOC the Sz=+-1 HS states are high-energy excitations. Thus, the system can be understood as a transverse field Ising model with the SOC playing the role of the transverse field. Consistent with this, we find a quantum phase transition between the THS phase and a quantum disordered (QD) phase. However, if the magnetic coupling is non-zero or the HS and LS states of a single molecule are non-degenerate the Z2 (Ising) symmetry is broken and the phase transition becomes a crossover. Thus, the QD phase and the THS phases are adiabatically connected, as, equivalently, are the large-D phase of the spin-one Heisenberg model and the quantum disordered phase of the transverse field Ising model. We also find a ferroelastic LS phase, and antierroelastic phase, with alternating HS and LS complexes, and a dimer phase, which results from the competition between antiferromagnetic and antiferroelastic interactions.