Nanoengineering room temperature ferroelectricity into orthorhombic SmMnO3 films

Orthorhombic R MnO 3 ( R  = rare-earth cation) compounds are type-II multiferroics induced by inversion-symmetry-breaking of spin order. They hold promise for magneto-electric devices. However, no spontaneous room-temperature ferroic property has been observed to date in orthorhombic R MnO 3 . Here,...

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Bibliographic Details
Published in:Nature communications 2020-05, Vol.11 (1), p.2207-2207, Article 2207
Main Authors: Choi, Eun-Mi, Maity, Tuhin, Kursumovic, Ahmed, Lu, Ping, Bi, Zenxhing, Yu, Shukai, Park, Yoonsang, Zhu, Bonan, Wu, Rui, Gopalan, Venkatraman, Wang, Haiyan, MacManus-Driscoll, Judith L.
Format: Article
Language:English
Subjects:
147/137
147/143
147/3
639/301
639/301/119
639/301/119/996
Antiferromagnetism
Broken symmetry
Compressive properties
CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY
Condensed-matter physics
Coupling
Density functional theory
Electric devices
Electric polarization
Exchanging
Ferroelectric materials
Ferroelectricity
ferroelectrics and multiferroics
Ferromagnetism
Humanities and Social Sciences
Magnetic properties
Magnetism
materials science
multidisciplinary
Multiferroic materials
Nanocomposites
Nanoengineering
Rare earth elements
Room temperature
Science
Science (multidisciplinary)
Tuning
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Summary:Orthorhombic R MnO 3 ( R  = rare-earth cation) compounds are type-II multiferroics induced by inversion-symmetry-breaking of spin order. They hold promise for magneto-electric devices. However, no spontaneous room-temperature ferroic property has been observed to date in orthorhombic R MnO 3 . Here, using 3D straining in nanocomposite films of (SmMnO 3 ) 0.5 ((Bi,Sm) 2 O 3 ) 0.5 , we demonstrate room temperature ferroelectricity and ferromagnetism with T C,FM  ~ 90 K, matching exactly with theoretical predictions for the induced strain levels. Large in-plane compressive and out-of-plane tensile strains (−3.6% and +4.9%, respectively) were induced by the stiff (Bi,Sm) 2 O 3 nanopillars embedded. The room temperature electric polarization is comparable to other spin-driven ferroelectric R MnO 3 films. Also, while bulk SmMnO 3 is antiferromagnetic, ferromagnetism was induced in the composite films. The Mn-O bond angles and lengths determined from density functional theory explain the origin of the ferroelectricity, i.e. modification of the exchange coupling. Our structural tuning method gives a route to designing multiferroics. Multiferroic materials exhibiting ferromagnetism (FM) and ferroeletricity (FE) at room temperature (RT) are promising for applications. Here, the authors demonstrate by inducing strain in SmMnO3 via introducing vertically aligned nanocomposites that exchange coupling can be modified tuning the system from anti-FM to FM and simultaneously inducing FE at RT.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-020-16101-2