Revealing the nature of antiferro-quadrupolar ordering in Cerium Hexaboride: CeB6

Abstract

Cerium-hexaboride (CeB6) f-electron compound displays a rich array of low-temperature magnetic phenomena, including `magnetically hidden' order, identified as multipolar in origin via advanced x-ray scattering. From first-principles electronic-structure results, we find that the antiferro-quadrupolar (AFQ) ordering in CeB6 arises from crystal-field splitting and yields band structure in agreement with experiments. With interactions of p-electrons between Ce and B6 being small, the electronic state of CeB6 is suitably described as Ce(4f1)3+(e-)(B6)2-. The AFQ state of orbital spins is caused by an exchange interaction induced through spin-orbit interaction, which also splits J=5/2 state into 8 ground state and 7 excited state. Within the smallest antiferromagnetic (111) configuration, an orbital-ordered AFQ state appears during charge self-consistency, and supports the appearance of `hidden' order. Hydrostatic pressure (either applied or chemically induced) stabilizes the AFM (AFQ) states over a ferromagnetic one, as observed at low temperatures.