Electrically controllable spontaneous magnetism in nanoscale mixed phase multiferroics

He, Qing; Chu, Ying Hao; Heron, John T.; Yang, So Young; Liang, Wen I.; Kuo, Chang‐Yang; Lin, Hong Ji; Yu, Pu; Chen, Liang; Zeches, R. J.; Kuo, Wen-Chuan; Juang, Jenh‐Yih; Chen, C. T.; Arenholz, Elke; Schöll, A.; Ramesh, R.

doi:10.1038/ncomms1221

Cited by 167 publications

(160 citation statements)

References 24 publications

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“…In specific, the Fe peak is centred at 710.8 eV, in good agreement with the expected value of 711 eV for Fe 3 þ , suggesting phase purity and a low-enough level of oxygen vacancies that they were not detected via XPS 40 . These data thus provide good evidence that the high M s values reported below do not arise from oxygen vacancies, as seen in some other sol-gel-derived materials, but more likely stem from strain effects, in closer analogy to epitaxial BFO systems 22,23,25 .…”

Section: Structural Characterizationsupporting

confidence: 54%

“…We also note that the low M s values in all unpoled samples preclude the possibility that iron oxide impurities or oxygen vacancies, as discussed above, from the sol-gel synthesis are the source of the high magnetization in poled samples. These M s values for electrically poled mesoporous BFO films demonstrate the highest values recorded for BFO films to date, greater even than values ranging from 0.2-0.5 m b per Fe reported in epitaxially strained BFO thin films 23,25 . Indeed, this magnetization change corresponds to a magnetoelectric coupling constant a ¼ m 0 DM/ E ¼ 1 Â 10 À 5 sm À 1 , which is on par with composite systems and much larger than that expected for single phase materials 42,43 .…”

Section: Structural Characterizationmentioning

confidence: 90%

“…For BFO in specific, thin films engineered with epitaxial strain show M S values up to 0.5 Bohr magnetons (m b ) per Fe (refs 22,25), which is substantially higher than the bulk value of 0.05 m b per Fe (refs 22,26). High values of 0.2-0.3 m b per Fe were also observed in highly strained mixed-phase (rhombohedral:super-tetragonal) epitaxial BFO 23 . While epitaxial strain in BFO has provided a fruitful method to tune materials properties, bulk, thin film, and nanostructured BFO have been made using a number of methods 12,14,19,[27][28][29][30][31][32][33][34][35][36][37] .…”

mentioning

confidence: 87%

“…For example, epitaxy has been used to amplify magnetic polarizations in BFO and other materials by the introduction of lattice strains 5,[19][20][21][22][23] . Epitaxial strain has also been used to convert materials that are neither ferroelectric nor ferromagnetic to multiferroics at low temperatures 24 .…”

mentioning

confidence: 99%

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Mesoporous bismuth ferrite with amplified magnetoelectric coupling and electric field-induced ferrimagnetism

et al. 2015

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Coupled ferromagnetic and ferroelectric materials, known as multiferroics, are an important class of materials that allow magnetism to be manipulated through the application of electric fields. Bismuth ferrite, BiFeO 3 , is the most-studied intrinsic magnetoelectric multiferroic because it maintains both ferroelectric and magnetic ordering to well above room temperature. Here we report the use of epitaxy-free wet chemical methods to create strained nanoporous BiFeO 3 . We find that the strained material shows large changes in saturation magnetization on application of an electric field, changing from 0.04 to 0.84 m b per Fe. For comparison, non-porous films produced using analogous methods change from just 0.002 to 0.01 m b per Fe on application of the same electric field. The results indicate that nanoscale architecture can complement strain-layer epitaxy as a tool to strain engineer magnetoelectric materials.

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Section: Structural Characterizationsupporting

confidence: 54%

Section: Structural Characterizationmentioning

confidence: 90%

mentioning

confidence: 87%

mentioning

confidence: 99%

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Mesoporous bismuth ferrite with amplified magnetoelectric coupling and electric field-induced ferrimagnetism

et al. 2015

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“…6-8 emu ml −1 ) is not observable by the XMCD technique owing to the small magnitude of the moment. Our work has shown that this enhanced magnetic moment in the highly strained Rphase disappears around 150 • C; further, application of an electric field converts this mixed phase into the T-phase, and the enhanced magnetic moment disappears; reversal of the field brings the mixed phase back accompanied by the magnetic moment in the distorted R-phase [20]. These observations raise several questions: first, what is the magnetic state of the strained R-phase?…”

Section: Phase Control Through Epitaxial Constraintsmentioning

confidence: 85%

Electric field control of ferromagnetism using multi-ferroics: the bismuth ferrite story

Ramesh

2014

Phil. Trans. R. Soc. A.

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Since the re-emergence of multi-ferroics and magnetoelectrics almost a decade ago, bismuth ferrite has been among the most heavily studied model system. It is a multi-ferroic with robust ferroelectricity and antiferromagnetism, in conjunction with weak ferromagnetism arising primarily from spin–orbit coupling effects. This material system has generated a significant amount of discussion in the community, because many of the physical properties measured in thin films are different from the bulk. This paper summarizes some of the key observations in this versatile materials system, with a particular focus on thin films, heterostructures and interfacial phenomena.

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Domain Wall Conduction and Polarization‐Mediated Transport in Ferroelectrics

Vasudevan

Guest

et al. 2013

Adv Funct Materials

120

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Nanometer‐scale electronic transport in engineered interfaces in ferroelectrics, such as domains and topological defects, has emerged as a topic of broad interest due to potential applications in information storage, sensors and photovoltaic devices. Scanning probe microscopy (SPM) methods led to rapid growth in the field by enabling correlation of the unique functional properties with microstructural features in the aforementioned highly localized phenomena. In addition to conduction localized at interfaces, polarization‐mediated control of conduction through domains in nanoscale ferroelectrics suggests significant potential for use in memristor technologies. In parallel with experiment, theory based on thermodynamic Landau‐Ginzburg‐Devonshire (LGD) framework has seen rapid development, both rationalizing the observations, and hinting at possibilities for local, deterministic control of order parameters. These theories can successfully account for static interface conductivity at charged, nominally uncharged and topologically protected domain walls. Here, recent experimental and theoretical progress in SPM‐motivated studies on domain wall conduction in both standard and improper ferroelectrics are reviewed. SPM studies on transport through ferroelectrics reveal that both domains and topological defects in oxides can be exploited as individual elements for use in functional nanoscale devices. Future prospects of the field are discussed.

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Electrically controllable spontaneous magnetism in nanoscale mixed phase multiferroics

Cited by 167 publications

References 24 publications

Mesoporous bismuth ferrite with amplified magnetoelectric coupling and electric field-induced ferrimagnetism

Mesoporous bismuth ferrite with amplified magnetoelectric coupling and electric field-induced ferrimagnetism

Electric field control of ferromagnetism using multi-ferroics: the bismuth ferrite story

Domain Wall Conduction and Polarization‐Mediated Transport in Ferroelectrics

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