Interfacial Ferromagnetism and Exchange Bias in<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:msub><mml:mi>CaRuO</mml:mi><mml:mn>3</mml:mn></mml:msub><mml:mo>/</mml:mo><mml:msub><mml:mi>CaMnO</mml:mi><mml:mn>3</mml:mn></mml:msub></mml:math>Superlattices

He, Chao; Grutter, Alexander J.; Gu, Meng; Browning, Nigel D.; Takamura, Yayoi; Kirby, Brian J.; Borchers, J. A.; Kim, Jae Wook; Fitzsimmons, M. R.; Zhai, Xiaofang; Mehta, Virat; Wong, Franklin J.; Suzuki, Yuri

doi:10.1103/physrevlett.109.197202

Cited by 93 publications

(82 citation statements)

References 19 publications

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“…At oxide interfaces, charge transfer can be driven by a difference in chemical potential or by screening of local dipoles. Charge transfer can alter the B -site valence states near the interface, enabling magnetic order that is distinct from either constituent, for instance leading to ferromagnetism confined to the interface between two insulating antiferromagnets [Salvador et al ., 1999; Lin et al ., 2006; Santos et al ., 2011] or ferromagnetism from a paramagnetic metal and antiferromagnetic insulator [Takahashi et al ., 2001; Nanda et al ., 2007; Freeland et al ., 2010; He et al ., 2012]. The spatial extent of the interfacial magnetism closely matches that of the charge transfer length scale, which is generally quite short, around 0.4 nm to 2 nm [Santos et al ., 2011; Grutter et al ., 2013; Hoffman et al ., 2013], owing to both the large dielectric constant and significant carrier concentration (charge density) that complex oxides often support [Ahn et al ., 2006].…”

Section: Emergent Magnetism At Interfacesmentioning

confidence: 99%

Interface-induced phenomena in magnetism

et al. 2017

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This article reviews static and dynamic interfacial effects in magnetism, focusing on interfacially-driven magnetic effects and phenomena associated with spin-orbit coupling and intrinsic symmetry breaking at interfaces. It provides a historical background and literature survey, but focuses on recent progress, identifying the most exciting new scientific results and pointing to promising future research directions. It starts with an introduction and overview of how basic magnetic properties are affected by interfaces, then turns to a discussion of charge and spin transport through and near interfaces and how these can be used to control the properties of the magnetic layer. Important concepts include spin accumulation, spin currents, spin transfer torque, and spin pumping. An overview is provided to the current state of knowledge and existing review literature on interfacial effects such as exchange bias, exchange spring magnets, spin Hall effect, oxide heterostructures, and topological insulators. The article highlights recent discoveries of interface-induced magnetism and non-collinear spin textures, non-linear dynamics including spin torque transfer and magnetization reversal induced by interfaces, and interfacial effects in ultrafast magnetization processes.

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Section: Emergent Magnetism At Interfacesmentioning

confidence: 99%

Interface-induced phenomena in magnetism

et al. 2017

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“…Observation of EB in the disordered-ordered magnetic interfaces, i.e. , in paramagnetic (PM) LaNiO 3 and FM LaMnO 3 superlattice and the PM CaRuO 3 and AFM CaMnO 3 superlattices are clearly the recent important discoveries in this area1213. More recently, strain engineered unexpected EB with the emergence of a self assembled spin glass like phase of LaSrMnO 4 at the film/substrate interface was reported for (La,Sr)MnO 3 single thin-films17.…”

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confidence: 99%

“…Overall the progress in EB has been two-fold. First, the EB has been addressed in unconventional heterostructures/bilayers with FM-PM, AFM-PM and collinear-noncollinear magnetic heterostructures7121316. This has challenged our present understanding of EB which is generally observed in conventional FM-AFM heterostructures1415.…”

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confidence: 99%

Positive exchange-bias and giant vertical hysteretic shift in La0.3Sr0.7FeO3/SrRuO3 bilayers

Rana

Pandey

Singh

et al. 2014

Sci Rep

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The exchange-bias effects in the mosaic epitaxial bilayers of the itinerant ferromagnet (FM) SrRuO3 and the antiferromagnetic (AFM) charge-ordered La0.3Sr0.7FeO3 were investigated. An uncharacteristic low-field positive exchange bias, a cooling-field driven reversal of positive to negative exchange-bias and a layer thickness optimised unusual vertical magnetization shift were all novel facets of exchange bias realized for the first time in magnetic oxides. The successive magnetic training induces a transition from positive to negative exchange bias regime with changes in domain configurations. These observations are well corroborated by the hysteretic loop asymmetries which display the modifications in the AFM spin correlations. These exotic features emphasize the key role of i) mosaic disorder induced subtle interplay of competing AFM-superexchange and FM double exchange at the exchange biased interface and, ii) training induced irrecoverable alterations in the AFM spin structure.

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“…[7][8][9][10][11] In a flurry of recent studies, ultrathin manganite films were incorporated in epitaxial heterostructures as a result of expectation of emergent physics such as tailored interfacial magnetic coupling and geometrically confined doping in such artificial lowdimensional systems. [12][13][14][15] Epitaxial superlattices (SLs) of complex oxides give access to fascinating physical phenomena as a result of magnetic frustration, charge transfer, and orbital reconstruction across interfaces. [16][17][18][19][20][21][22] In particular, exchange bias, as a prototypical interfacial magnetic interaction between different spin orders, was reported in some manganite-based heterostructures and SLs.…”

mentioning

confidence: 99%