Magnetic Dynamics in Heavy-Fermion Systems with Multipolar Ordering Studied by Neutron Scattering

Abstract

Despite more than half a century of studies in heavy-fermion compounds, a full understanding of the various possible magnetic ordering phenomena is still far from complete. Some heavy-fermion materials show so-called hidden-order phases, which are invisible to conventional diffraction techniques. The multipolar moments of the f-electrons in their specific crystal field environment play a decisive role in the formation of these phases. Such hidden-order phases have been observed in a variety of compounds containing 4f and 5f elements, like URu2Si2, NpO2, YbRu2Ge2, and CeB6. The competition or coexistence of multipolar ordering with more conventional magnetic order parameters, such as ferro- or antiferromagnetism, gives rise to complex magnetic-field-temperature phase diagrams in these compounds that provide a rich playground for experimental and theoretical investigations. Here I examine the pure and La-doped f-electron system CeB6, as well as Ce3Pd20Si6, by means of neutron scattering. The magnetic field dependence of the zone center exciton mode in CeB6 was studied in fields up to 14.5 T and compared with the existing theory. A long standing question of the applicability of the phenomenological temperature dependence =k BT K+A T, where T K is the Kondo temperature, for two limiting cases, the Kondo lattice and Kondo impurity, has been investigated on a set of samples diluted with lanthanum. In Ce3Pd20Si6, the order parameter of the AFQ phase was uncovered, and its field dependence was studied in fields up to 9 T.