A multiferroic on the brink: Uncovering the nuances of strain-induced transitions in BiFeO3

Sando, Daniel; Xu, Bin; Bellaïche, L.; Nagarajan, V.

doi:10.1063/1.4944558

Cited by 104 publications

(132 citation statements)

References 133 publications

(187 reference statements)

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“…The uneven intensity distribution between the observed quarter-order peaks suggests that there is a preferred orientation, which is likely the result of the orthorhombic nature of the DyScO 3 substrate. 37 The lattice parameters of the second phase observed in the heterostructures grown on DyScO 3 of additional reflections in the diffraction pattern supports this conclusion as both superstructured phases would have clear superlattice spots. The second region, within a lighter contrast stripe, has a SAED pattern (Figure 3c), which is consistent with the RSM studies, where superlattice spots corresponding to the highlighted 1/4 (01̅ 1) reflections (as marked by the arrows, Figure 3c) indicate that the region exhibits an antipolar structure with a space group of Pbam.…”

Section: ■ Results and Discussionsupporting

confidence: 61%

“…Figure S2). This stripe morphology and its thickness-dependent evolution are reminiscent of a strainmediated, mixed-phase structure with enhanced electromechanical response in highly strained BiFeO 3 films 34 and suggest that there could be strain-induced phase coexistence in heterostructures grown on DyScO 3 .…”

Section: ■ Results and Discussionmentioning

confidence: 98%

“…The second region, within a lighter contrast stripe, has a SAED pattern (Figure 3c), which is consistent with the RSM studies, where superlattice spots corresponding to the highlighted 1/4 (01̅ 1) reflections (as marked by the arrows, Figure 3c) indicate that the region exhibits an antipolar structure with a space group of Pbam. Thus, it appears that at small strains, as is the case for films grown on DyScO 3 substrates, an intimate mixture of the two nanoscale phases is observed. This demonstrated ability to control phase stability using epitaxial strain in Bi 0.7 La 0.3 FeO 3 has not been previously reported.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…Below, we will describe additional studies that confirm that this diffraction pattern arises from two phases. The data together with additional RSM studies at different diffraction conditions (Supporting Information, Figures S3− S5) allow for the extraction of the unit-cell parameters for the various phases, which are thus summarized ( Figure 2d); this includes two distinct phases for the films grown on SrTiO 3 and GdScO 3 and a mixture of phases on DyScO 3 . To further understand the nature of the crystal structures, various RSM studies were conducted to investigate quarterorder diffraction peaks (as their presence indicates a structure which is compatible with antipolar order).…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…It is important to note that the heterostructures grown on GdScO 3 are expected to show antiferroelectric-like behavior as the measurement started from negative bias, poling the sample into the antipolar (and potentially antiferroelectric-like) state for the remainder of the measurement. Heterostructures grown on SrTiO 3 and DyScO 3 are expected to show antipolar (and potentially antiferroelectric-like) behavior regardless of starting voltage because of their as-grown Pbam phase that is further reinforced by the applied bias. This is all consistent with what is expected for the antipolar Pbam phase.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

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Strain-Driven Nanoscale Phase Competition near the Antipolar–Nonpolar Phase Boundary in Bi_0.7La_0.3FeO₃ Thin Films

Dedon

Chen

et al. 2018

ACS Appl. Mater. Interfaces

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Complex-oxide materials tuned to be near phase boundaries via chemistry/composition, temperature, pressure, etc. are known to exhibit large susceptibilities. Here, we observe a strain-driven nanoscale phase competition in epitaxially constrained Bi 0.7 La 0.3 FeO 3 thin films near the antipolar−nonpolar phase boundary and explore the evolution of the structural, dielectric, (anti)ferroelectric, and magnetic properties with strain. We find that compressive and tensile strains can stabilize an antipolar PbZrO 3 -like Pbam phase and a nonpolar Pnma orthorhombic phase, respectively. Heterostructures grown with little to no strain exhibit a self-assembled nanoscale mixture of the two orthorhombic phases, wherein the relative fraction of each phase can be modified with film thickness. Subsequent investigation of the dielectric and (anti)ferroelectric properties reveals an electric-field-driven phase transformation from the nonpolar phase to the antipolar phase. X-ray linear dichroism reveals that the antiferromagnetic-spin axes can be effectively modified by the straininduced phase transition. This evolution of antiferromagnetic-spin axes can be leveraged in exchange coupling between the antiferromagnetic Bi 0.7 La 0.3 FeO 3 and a ferromagnetic Co 0.9 Fe 0.1 layer to tune the ferromagnetic easy axis of the Co 0.9 Fe 0.1 . These results demonstrate that besides chemical alloying, epitaxial strain is an alternative and effective way to modify subtle phase relations and tune physical properties in rare earth-alloyed BiFeO 3 . Furthermore, the observation of antiferroelectricantiferromagnetic properties in the Pbam Bi 0.7 La 0.3 FeO 3 phase could be of significant scientific interest and great potential in magnetoelectric devices because of its dual antiferroic nature.

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Section: ■ Results and Discussionsupporting

confidence: 61%

Section: ■ Results and Discussionmentioning

confidence: 98%

Section: ■ Results and Discussionmentioning

confidence: 99%

Section: ■ Results and Discussionmentioning

confidence: 99%

Section: ■ Results and Discussionmentioning

confidence: 99%

See 3 more Smart Citations

Strain-Driven Nanoscale Phase Competition near the Antipolar–Nonpolar Phase Boundary in Bi_0.7La_0.3FeO₃ Thin Films

Dedon

Chen

et al. 2018

ACS Appl. Mater. Interfaces

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A study of polymorph dynamics in mixed‐phase BiFeO3 thin films via AFM and in‐situ TEM applications of external stimuli

Holsgrove¹,

Duchamp

Edwards³

et al. 2016

European Microscopy Congress 2016: Proceedings

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Epitaxially strained BiFeO 3 (BFO) thin films have seen an upsurge of interest over the past decade with the revelation of fascinating characteristics such as giant ferroelectric polarisation, exceptional piezoelectric and magnetoelectric responses to name a few. [1] The growth of BFO on substrates providing a large in‐plane compressive strain which facilitates structural alterations of the material to that of a tetragonal‐like phase (T‐phase) and distorted rhombohedral‐like phase (R‐phase) has opened the door to a plethora of opportunities in terms of controlling nanoscale interfaces and expanding our understanding of solid state physics. In a recent review by Nagarajan et al. (2016), [2] it was advised that there are still a number of exciting possibilities as well as pending questions which need to be addressed before the functionality of mixed‐phase BFO thin films can be driven to the next level. Using both aberration‐corrected TEM and STEM we have performed a high resolution study of the lattice parameters which characterise the ‘R’ and ‘T’ phase (Figure 1) and mapped the strain evolution (via geometrical phase analysis (GPA)) between polymorphs using the LaAlO 3 substrate as reference. Having identified the metastable ‘T’ polymorph and the extent to which the thin film (and FIB‐prepared lamella) thickness can influence the ratio of ‘R’ to ‘T’ polymorphs, we demonstrate the thermal energy required to expand the dimensions of the highly strained ‘T’ polymorph through in‐situ heat cycling experiments (Figure 2), and explain the complexity involved in such a transition. The relative ease through which transitions from one phase to another can be achieved varies depending on the application of stimuli selected. In this study we use a variation of techniques to explore the physical phenomena behind the functionality of mixed‐phase BFO. We highlight the benefits of reversibly reorganising phases via the application of external stimuli with an AFM probe tip. Through precise SEM and FIB techniques we have identified the pre‐written AFM areas and milled cross‐sectional lamellae across these areas for post‐AFM analysis using STEM. With this unique study we detect and compare structural differences between the as‐grown polymorphs in a native lamella and polymorphs written through external stimuli via an AFM tip. We show differences in lattice parameters and strain evolution in the newly written polymorphs via nano‐beam electron diffraction using a 2nm sized electron probe; this precision has allowed us to explicitly map the strain across a large area of these polymorphs. With the addition of EELS focusing on the Fe‐ L 2,3 and O‐ K edges we show changes in ELNES features which suggest octahedral distortion variations between polymorphs. By combining AFM and state‐of‐the‐art STEM techniques in this distinctive way we provide an insight into the link between exciting interfacial behaviour seen via AFM at the polymorph boundaries on the microscopic scale, and structural polymorph changes seen via STEM on the atomic scale.

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2023

Nonlinear Optics on Ferroic Materials

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A multiferroic on the brink: Uncovering the nuances of strain-induced transitions in BiFeO3

Cited by 104 publications

References 133 publications

Strain-Driven Nanoscale Phase Competition near the Antipolar–Nonpolar Phase Boundary in Bi_0.7La_0.3FeO₃ Thin Films

Strain-Driven Nanoscale Phase Competition near the Antipolar–Nonpolar Phase Boundary in Bi_0.7La_0.3FeO₃ Thin Films

A study of polymorph dynamics in mixed‐phase BiFeO3 thin films via AFM and in‐situ TEM applications of external stimuli

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A multiferroic on the brink: Uncovering the nuances of strain-induced transitions in BiFeO3

Cited by 104 publications

References 133 publications

Strain-Driven Nanoscale Phase Competition near the Antipolar–Nonpolar Phase Boundary in Bi0.7La0.3FeO3 Thin Films

Strain-Driven Nanoscale Phase Competition near the Antipolar–Nonpolar Phase Boundary in Bi0.7La0.3FeO3 Thin Films

A study of polymorph dynamics in mixed‐phase BiFeO3 thin films via AFM and in‐situ TEM applications of external stimuli

References

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Strain-Driven Nanoscale Phase Competition near the Antipolar–Nonpolar Phase Boundary in Bi_0.7La_0.3FeO₃ Thin Films

Strain-Driven Nanoscale Phase Competition near the Antipolar–Nonpolar Phase Boundary in Bi_0.7La_0.3FeO₃ Thin Films