Self-assembled three-dimensional framework of PbTiO3:ε-Fe2O3 nanostructures with room temperature multiferroism

[Display omitted] •The 3D framework of PTO:ε-FO with room temperature multiferroism was prepared.•The mechanism of remarkable multiferroic performance of PTO:ε-FO was elucidated.•Preferential epitaxy of resistive PTO allows suppressed leakage current.•The morphology and connectivity were tuned by mo...

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Bibliographic Details
Published in:Applied surface science 2021-04, Vol.544, p.148945, Article 148945
Main Authors: Cao, Yi, Wu, Bo, Zhu, Yin-Lian, Wang, Yu-Jia, Tang, Yun-Long, Liu, Nan, Liu, Jia-Qi, Ma, Xiu-Liang
Format: Article
Language:English
Subjects:
Composite multiferroics
Magnetoelectric coupling
Preferential epitaxy
Scanning probe microscopy
Strain engineering
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Summary:[Display omitted] •The 3D framework of PTO:ε-FO with room temperature multiferroism was prepared.•The mechanism of remarkable multiferroic performance of PTO:ε-FO was elucidated.•Preferential epitaxy of resistive PTO allows suppressed leakage current.•The morphology and connectivity were tuned by modifying epitaxial strain state. Hybrid multiferroic systems composed of complex oxides have drawn sustained attention for decades due to their intriguing physical effects and potential technological exploitations. Designing innovative nanostructures of multiferroic nanocomposites to overcome inherent shortcomings for conventional layered (e.g. clamping effect) and vertically aligned (e.g. leaky) films are instrumental to realize genuine multiferroic behaviors. Here the self-assembled architecture with three-dimensional (3D) framework of heterostructures is fabricated, wherein well-ordered multiferroic ε-Fe2O3 (ε-FO) nanoboats are embedded in a ferroelectric perovskite PbTiO3 (PTO) matrix. The biphasic system combines strong interfacial magnetoelectric couplings of vertically aligned heterostructure and addressed leakage issue via preferential epitaxy of a high-resistance transition layer of PTO. Additionally, the two phases maintain full lattice coherence along vertical interfaces allowing for efficient interfacial strain coupling. Ferroelectricity and piezoelectric switching of the 3D nanostructured PTO:ε-FO film have been corroborated macroscopically by polarization hysteresis (Ps ~ 45 μC cm−2) and locally by piezoresponse force microscopy, and strong magnetoelectric coupling has been manifested as a sizable modification of piezoelectric switching characteristics via applying a DC magnetic field, all conducting at room temperature. The novel 3D multiferroic-ferroelectric heterostructure offers great potential for nanoengineering of multiferroic composites, thus opens an avenue towards superior microelectronics and spintronics.
ISSN:0169-4332
1873-5584
DOI:10.1016/j.apsusc.2021.148945