Competing spin-orbital singlet states in the 4d4 honeycomb ruthenate Ag3LiRu2O6
Abstract
When spin-orbit-entangled d-electrons reside on a honeycomb lattice, rich quantum states are anticipated to emerge, as exemplified by the d5 Kitaev materials. Distinct yet equally intriguing physics may be realized with a d-electron count other than d5. We found that the layered ruthenate Ag3LiRu2O6 with d4 Ru4+ ions at ambient pressure forms a honeycomb lattice of spin-orbit-entangled singlets, which is a playground for frustrated excitonic magnetism. Under pressure, the singlet state does not develop the expected excitonic magnetism but experiences two successive transitions to other nonmagnetic phases, first to an intermediate phase with moderate distortion of honeycomb lattice, and eventually to a high-pressure phase with very short Ru-Ru dimer bonds. While the strong dimerization in the high-pressure phase originates from a molecular orbital formation as in the sister compound Li2RuO3, the intermediate phase represents a spin-orbit-coupled J-dimer state which is stabilized by the admixture of upper-lying J eff = 1-derived states. We argue that the J-dimer state is induced by a pseudo-Jahn-Teller effect associated with the low-lying spin-orbital excited states and is unique to spin-orbit-entangled d4 systems. The discovery of competing singlet phases demonstrates rich spin-orbital physics of d4 honeycomb compounds and paves the way for realization of unconventional magnetism.
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