Formation of orbital molecules on a pyrochlore lattice induced by A-O bond covalency

Abstract

The pyrochlore ruthenate In2Ru2O7 displays a subtle competition between spin-orbital entanglement and molecular orbital formation. At room temperature, a spin-orbit-entangled singlet state was identified. With decreasing temperature, In2Ru2O7 undergoes multiple structural transitions and eventually forms a nonmagnetic ground state with semi-isolated Ru2O units on the pyrochlore lattice. The dominant hopping through the Ru-O-Ru linkage leads to molecular orbital formation within the Ru2O units. This molecular orbital formation is unique in that it involves the O2- anions, unlike the transition-metal dimers observed in systems with edge-sharing octahedra. We argue that the covalent character of In-O bonds plays a pivotal role in the structural transitions and molecular orbital formation and such bonding character of "A-site" ions is an important ingredient for electronic phase competition in complex transition metal oxides.