Physical Review Research (Aug 2022)

Bond ordering and molecular spin-orbital fluctuations in the cluster Mott insulator GaTa_{4}Se_{8}

  • Tsung-Han Yang,
  • S. Kawamoto,
  • Tomoya Higo,
  • SuYin Grass Wang,
  • M. B. Stone,
  • Joerg Neuefeind,
  • Jacob P. C. Ruff,
  • A. M. Milinda Abeykoon,
  • Yu-Sheng Chen,
  • S. Nakatsuji,
  • K. W. Plumb

DOI
https://doi.org/10.1103/PhysRevResearch.4.033123
Journal volume & issue
Vol. 4, no. 3
p. 033123

Abstract

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For materials where spin-orbit coupling is competitive with electronic correlations, the spatially anisotropic spin-orbital wave functions 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 GaTa_{4}Se_{8}. Above T^{*}, GaTa_{4}Se_{8} has an average cubic crystal structure, but total scattering measurements indicate local noncubic distortions of Ta_{4} 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.