Direct confirmation of long-range magnetic order and evidence for multipoles in Ce2O3

Abstract

The sesquioxide, Ce2O3, has been a material of intense interest in recent years due to reports of an anomalous giant magnetodielectric effect and emergent mixed crystal field-phonon (vibronic) excitations below a putative antiferromagnetic transition at TN = 6.2 K. The claim of long-range magnetic order in this material is based on heat capacity and temperature-dependent susceptibility measurements; however, multiple neutron diffraction studies have been unable to distinguish any magnetic Bragg peaks. In this article, we present the results of a comprehensive investigation of the low-temperature phase in symmetry-broken polycrystalline Ce2O3 using a combination of magnetic susceptibility, heat capacity, neutron diffraction, triple-axis and time-of-flight (TOF) inelastic neutron scattering (INS), and muon spin rotation (μSR). Our measurements and subsequent analysis confirm that the transition at TN can be associated with the ordering of moments on the Ce3+ site. Both a spontaneous magnetic order observed with μSR and a dispersive spin-wave spectrum observed with inelastic neutron scattering suggest a model wherein planar dipoles order antiferromagnetically. Notable inconsistencies between μSR and neutron scattering data within the dipole picture provide strong evidence for the ordering of higher-order moments.