Litcius/Paper detail

Significantly Enhanced Room-Temperature Ferromagnetism in Multiferroic EuFeO<sub>3−δ</sub> Thin Films

Hao Li, Yali Yang, Shiqing Deng, Hui Liu, Tianyu Li, Yuzhu Song, He Bai, Tao Zhu, Jiaou Wang, Huanhua Wang, Er‐Jia Guo, Xianran Xing, Hongjun Xiang, Jun Chen

2023Nano Letters13 citationsDOI

Abstract

Regulating the magnetic properties of multiferroics lays the foundation for their prospective application in spintronic devices. Single-phase multiferroics, such as rare-earth ferrites, are promising candidates; however, they typically exhibit weak magnetism at room temperature (RT). Here, we significantly boosted the RT ferromagnetism of a representative ferrite, EuFeO 3, by oxygen defect engineering. Polarized neutron reflectometry and magnetometry measurements reveal that saturation magnetization reaches 0.04 μ B /Fe, which is approximately 5 times higher than its bulk phase. Combining the annular bright-field images with theoretical assessment, we unravel the underlying mechanism for magnetic enhancement, in which the decrease in Fe–O–Fe bond angles caused by oxygen vacancies ( V O ) strengthens magnetic interactions and tilts Fe spins. Furthermore, the internal relationship between magnetism and V O was established by illustrating how the magnetic structure and magnitude change with V O configuration and concentration. Our strategy for regulating magnetic properties can be applied to numerous functional oxide materials.

Topics & Concepts

MultiferroicsSpintronicsMagnetismMaterials scienceFerromagnetismCondensed matter physicsMagnetizationMagnetometerSpinsNuclear magnetic resonanceNanotechnologyMagnetic fieldFerroelectricityOptoelectronicsPhysicsDielectricQuantum mechanicsMultiferroics and related materialsMagnetic and transport properties of perovskites and related materialsAdvanced Condensed Matter Physics