Bond Ordering and Molecular Spin-Orbital Fluctuations in the Cluster Mott Insulator GaTa4Se8

Abstract

For materials where spin-orbit coupling is competitive with electronic correlations, the spatially anisotropic spin-orbital wavefunctions can stabilize degenerate states that lead to many and diverse quantum phases of matter. Here, we find evidence for a dynamical spin-orbital state preceding a T*=50 K order-disorder spin-orbital ordering transition in the j\!=\!3/2 lacunar spinel GaTa4Se8. Above T*, GaTa4Se8 has an average cubic crystal structure, but total scattering measurements indicate local non-cubic distortions of Ta4 tetrahedral clusters for all measured temperatures 2 < T < 300 K. Inelastic neutron scattering measurements reveal the dynamic nature of these local distortions through symmetry forbidden optical phonon modes that modulate j\!=\!3/2 molecular orbital occupation as well as intercluster Ta-Se bonds. Spin-orbital ordering at T* cannot be attributed to a classic Jahn-Teller mechanism and based on our findings, we propose that intercluster interactions acting on the scale of T* act to break global symmetry. The resulting staggered intercluster dimerization pattern doubles the unit cell, reflecting a spin-orbital valence bond ground state.