Enhanced Local Magnetization by Interface Engineering in Perovskite‐Type Correlated Oxide Heterostructures | Zendy

Huijben Mark | Zendy; Liu Yaohua | Zendy; Boschker Hans | Zendy; Lauter Valeria | Zendy; Egoavil Ricardo | Zendy; Verbeeck Jo | Zendy; te Velthuis Suzanne G. E. | Zendy; Rijnders Guus | Zendy; Koster Gertjan | Zendy

AI Assistant Blog Pricing

Home ZAIA Blog

Premium

Enhanced Local Magnetization by Interface Engineering in Perovskite‐Type Correlated Oxide Heterostructures

Author(s) -

Huijben Mark,

Liu Yaohua,

Boschker Hans,

Lauter Valeria,

Egoavil Ricardo,

Verbeeck Jo,

te Velthuis Suzanne G. E.,

Rijnders Guus,

Koster Gertjan

Publication year - 2015

Publication title -

advanced materials interfaces

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 1.671

H-Index - 65

ISSN - 2196-7350

DOI - 10.1002/admi.201400416

Subject(s) - materials science , neutron reflectometry , heterojunction , magnetization , stacking , perovskite (structure) , oxide , layer (electronics) , reflectometry , interface (matter) , condensed matter physics , nanotechnology , optoelectronics , chemical engineering , neutron , nuclear magnetic resonance , magnetic field , composite material , metallurgy , neutron scattering , time domain , capillary number , capillary action , computer science , quantum mechanics , computer vision , physics , small angle neutron scattering , engineering

Elimination of a magnetic dead‐layer at the LSMO/STO interface is achieved by interface engineering through incorporation of a single La 0.33 Sr 0.67 O layer. Controlled growth of interfacial atomic stacking in combination with local magnetic probing by polarized neutron reflectometry enables controlled interface engineering and results in optimal interfacial magnetization in perovskite‐type correlated oxide heterostructures.

This content is not available in your region!

Continue researching here.

Having issues? You can contact us here

Accelerating Research