Ordering of hidden multipoles in spin-orbital entangled 5d1 Ta chlorides

Abstract

Spin-orbit coupling of as large as a half eV for electrons in 5d orbitals often gives rise to the formation of spin-orbital entangled objects, characterized by the effective total angular momentum Jeff. Of particular interest are the Jeff = 3/2 states realized in 5d1 transition metal ions surrounded by an anion octahedron. The pure Jeff = 3/2 quartet does not have any magnetic dipolar moment (<M> = 0) but hosts hidden pseudo-dipolar moments accompanied by charge quadrupoles and magnetic octupoles. Cs2TaCl6 and Rb2TaCl6 are correlated insulators with 5d1 Ta4+ ions in a regular Cl octahedron. Here we demonstrate that these Ta chlorides have a substantially suppressed effective magnetic dipolar moment of ~ 0.2 μB. Two phase transitions are observed at low temperatures that are not pronounced in the magnetization but accompanied with large electronic entropy of Rln4. We ascribe the two transitions to the ordering of hidden multipoles.