Control of ferroelectricity and magnetism in multi-ferroic BiFeO
            <sub>3</sub>
            by epitaxial strain

Sando, Daniel; Agbelele, A.; Daumont, Christophe; Rahmedov, Dovran; Ren, Wei; Infante, I. C.; Lisenkov, S.; Prosandeev, S. A.; Fusil, S.; Jacquet, Éric; Carrétéro, C.; Petit, S.; Cazayous, M.; Juraszek, J.; Breton, J.M. Le; Bellaïche, L.; Dkhil, Brahim; Barthélémy, A.; Bibès, Manuel

doi:10.1098/rsta.2012.0438

Cited by 35 publications

(28 citation statements)

References 40 publications

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“…It is hard to model such a system as not only the desired orientation effect but also a completely different morphology applies for certain films and not for others (Pitfall 3). Complete coverage and nearly ideal interfaces have been obtained for other routes [76][77][78]. Concurrently, the introduction of dislocations has been found to play a large role at outer interfaces of ferroelectrics [76].…”

Section: Sample Preparation: Realistic Materials Morphologies and Implmentioning

confidence: 76%

“…Another method to introduce stress transformation from one phase to another can be performed by material engineering through epitaxial growth of two different crystals with a lattice mismatch of up to 5% [76,78]. Inducing a strain by a corresponding field related to a certain material will evoke stress in the other phase thus tuning the material properties of the non active phase [101].…”

Section: Strain Measurement At the Micron-scale And Interfacesmentioning

confidence: 99%

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Measuring the magnetoelectric effect across scales

et al. 2015

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Magnetoelectric coupling is the material based coupling between electric and magnetic fields without recurrence to electrodynamics. It can arise in intrinsic multiferroics as well as in composites. Intrinsic multiferroics rely on atomistic coupling mechanisms, or coupled crystallographic order parameters, and even more complex mechanisms. They typically require operating temperatures much below T = 0°C in order to exhibit their coupling effects. Room temperature applications are thus excluded. Consequently, composites have been designed to circumvent this limitation. They rely on field coupling between magnetostrictive and piezoelectric materials or in more advanced scenarios on quantum coupling in between both phases.This overview will describe experimental techniques and their particular limitations in accessing these coupling phenomena at different scales. Strain coupling is the dominant coupling mechanism at the macroscale as well as down to the micrometer. At the nanoscale more subtle effects can arise and some care has to be taken when investigating local coupling at interfaces using scanning probe techniques, e. g. due to semiconductor effects, field screening, or gradient and surface effects. At the smallest length scale atomic or molecular coupling can be tested using X‐ray dichroism or probe atoms like 57Fe in Mössbauer spectroscopy. We display a selection of measuring techniques at the different scales and outline possible pitfalls for experimentalists as well as theoreticians when using material parameters extracted from such experimental work. (© 2015 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)

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Section: Sample Preparation: Realistic Materials Morphologies and Implmentioning

confidence: 76%

Section: Strain Measurement At the Micron-scale And Interfacesmentioning

confidence: 99%

Measuring the magnetoelectric effect across scales

et al. 2015

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“…These results are presented in the supplementary materials. We note that previous studies have shown that the magnetic structure of these materials is very sensitive to strain, growth direction, and synthesis conditions 28,29 .…”

mentioning

confidence: 69%

Electric-Field Induced Reversible Switching of the Magnetic Easy Axis in Co/BiFeO₃ on SrTiO₃

Gao

Zhang

Ratcliff³

et al. 2017

Nano Lett.

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Electric-field (E-field) control of magnetism enabled by multiferroic materials has the potential to revolutionize the landscape of present memory devices plagued with high energy dissipation. To date, this E-field controlled multiferroic scheme has only been demonstrated at room temperature using BiFeO films grown on DyScO, a unique and expensive substrate, which gives rise to a particular ferroelectric domain pattern in BiFeO. Here, we demonstrate reversible electric-field-induced switching of the magnetic state of the Co layer in Co/BiFeO (BFO) (001) thin film heterostructures fabricated on (001) SrTiO (STO) substrates. The angular dependence of the coercivity and the remanent magnetization of the Co layer indicates that its easy axis reversibly switches back and forth 45° between the (100) and the (110) crystallographic directions of STO as a result of alternating application of positive and negative voltage pulses between the patterned top Co electrode layer and the (001) SrRuO (SRO) layer on which the ferroelectric BFO is epitaxially grown. The coercivity (H) of the Co layer exhibits a hysteretic behavior between two states as a function of voltage. A mechanism based on the intrinsic magnetoelectric coupling in multiferroic BFO involving projection of antiferromagnetic G-type domains is used to explain the observation. We have also measured the exact canting angle of the G-type domain in strained BFO films for the first time using neutron diffraction. These results suggest a pathway to integrating BFO-based devices on Si wafers for implementing low power consumption and nonvolatile magnetoelectronic devices.

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“…First-principles calculations [36] even predict that by simply depositing the room-temperature FM double perovskites Bi 2 NiReO 6 and Bi 2 MnReO 6 on a substrate strain should turn their antipolar bulk ground state into a FE one. For the materials already showing bulk FE, strain engineering has also been shown to be a powerful and flexible means of tailoring the properties of ABO 3 thin films [37,38] or superlattices [39]. The effect of epitaxial strain on the structure of the perovskite unit cell can induce a host of interesting effects, arising from either polar cation shifts or rotation of the oxygen octahedra, or both.…”

Section: Introductionmentioning

confidence: 98%

Selected multiferroic perovskite oxides containing rare earth and transition metal elements

Chen

et al. 2014

Chin. Sci. Bull.

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Multiferroic materials are currently the subject of intensive research worldwide, because of both their fundamental scientific problems and also possible technological applications. Among a number of candidates in the laboratories, compounds consisting of rare earth and transition metal perovskite oxides have very unusual structural and physical properties. In contrast to the so-called type I multiferroics, ferroelectricity may be induced by magnetic ordering or by applying external fields. In this review, the recent progress on the experimental and theoretical studies of some selected type II multiferroics is presented, with a focus on the perovskite oxides containing rare earth and transition metal elements. The rare earth orthoferrite crystals, rare earth titanate strained film, and rare earthbased superlattices are systematically reviewed to provide a broad overview on their promising electric, magnetic, and structural properties. The recent experimental advances in single-crystal growth by optical floating zone method are also presented. First-principles investigations, either supported by experimental results or awaiting for experimental verifications, are shown to offer useful guidance for the future applications of unconventional multiferroics.

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Control of ferroelectricity and magnetism in multi-ferroic BiFeO ₃ by epitaxial strain

Cited by 35 publications

References 40 publications

Measuring the magnetoelectric effect across scales

Measuring the magnetoelectric effect across scales

Electric-Field Induced Reversible Switching of the Magnetic Easy Axis in Co/BiFeO₃ on SrTiO₃

Selected multiferroic perovskite oxides containing rare earth and transition metal elements

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Control of ferroelectricity and magnetism in multi-ferroic BiFeO 3 by epitaxial strain

Cited by 35 publications

References 40 publications

Measuring the magnetoelectric effect across scales

Measuring the magnetoelectric effect across scales

Electric-Field Induced Reversible Switching of the Magnetic Easy Axis in Co/BiFeO3 on SrTiO3

Selected multiferroic perovskite oxides containing rare earth and transition metal elements

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Control of ferroelectricity and magnetism in multi-ferroic BiFeO ₃ by epitaxial strain

Electric-Field Induced Reversible Switching of the Magnetic Easy Axis in Co/BiFeO₃ on SrTiO₃