Standard microscopic approach to magnetic orders is based on assuming a
Heisenberg form for inter-atomic exchange interactions. These interactions are
considered as a driving force for the ordering transition with magnetic moments
serving as the primary order parameter. Any higher-rank multipoles appearing
simultaneously with such magnetic order are typically treated as auxiliary
order parameters rather than a principal cause of the transition. In this
study, we show that these traditional assumptions are violated in the case of
PrO2β. Evaluating the full set of Pr-Pr superexchange interactions from a
first-principles many-body technique we find that its unusual non-collinear 2k
magnetic structure stems from high-rank multipolar interactions, and that the
corresponding contribution of the Heisenberg interactions is negligible. The
observed magnetic order in PrO2β is thus auxiliary to high-rank "hidden"
multipoles. Within this picture we consistently account for previously
unexplained experimental observations like the magnitude of exchange splitting
and the evolution of magnetic structure in external field. Our findings
challenge the standard paradigm of observable magnetic moments being the
driving force for magnetic transitions.Comment: 13 pages + 4 pages of Supplementary, 3 Figure