Giant geometry modulation on magnetic proximity effect observed in isomeric oxide heterostructures

Magnetic proximity effect (MPE) is generally considered to occur at the magnetic-nonmagnetic material interface within a short-range space domain, while the structural geometry modulation on such an interface effect has not been explored. Here, we fabricate isomeric paramagnetic metallic IrO2 with rutile and anatase structures, respectively, on a ferrimagnetic insulating CoFe2O4, and study the MPE-induced magnetism by anomalous Hall effect (AHE) measurements. The rutile phase with layered structure shows a conventional AHE and identical coercive-field with CoFe2O4, indicating a concomitant magnetic switching as a result of a strong magnetic coupling at the interface. In contrast, the anatase phase with tetrahedral structure exhibits an unconventional AHE with negative coercive-field at low temperatures. Further analyses indicate that in anatase, the contribution that strongly couples with CoFe2O4 is dramatically suppressed while a giant frustration-like response emerges. Our findings reveal that the MPE-induced spin orders can be pronouncedly modulated by structural geometry.