Your search keyword '"Sando, D"' showing total 5 results

1. Insight into magnetic, ferroelectric and elastic properties of strained BiFeO3 thin films through Móssbauer spectroscopy.

Author

Agbelele, A., Sando, D., Infante, I. C., Carrétéro, C., Jouen, S., Le Breton, J.-M., Barthélémy, A., Dkhil, B., Bibes, M., and Juraszek, J.

Subjects

*MAGNETIC properties, *FERROELECTRICITY, *ELASTICITY, *BISMUTH compounds, *FERRITES, *MOSSBAUER spectroscopy

Abstract

We have studied the magnetic order of highly strained (001)-oriented BiFeO3 (BFO) thin films using 57Fe Conversion Electron Móssbauer Spectrometry. From 90K to 620K the films exhibit a collinear antiferromagnetic structure, in contrast with the cycloidal structure observed in bulk BFO. Moreover, we find that both the planar magnetic anisotropy for compressive strain and out-of-plane anisotropy for tensile strain persist from 90K up to the Néel temperature (TN), which itself shows only a weak strain dependence. An analysis of the line asymmetry of the paramagnetic doublet for temperatures above TN is used to reveal the strain-dependent rotation of the polarization direction, consistent with previous observations. Our results show that the lattice dynamics in BFO films are strongly strain-dependent, offering avenues toward acoustic phonon devices. Finally, we use the versatility of Móssbauer spectroscopy technique to reveal various multi-property features including magnetic states, polarization direction and elastic strain. [ABSTRACT FROM AUTHOR]

Published

2016

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

Author

Sando, D., Bin Xu, Bellaiche, L., and Nagarajan, V.

Subjects

*MULTIFERROIC materials, *BISMUTH, *FERRITES, *HEMATITE, *FERROELECTRIC materials

Abstract

Bismuth ferrite (BiFeO3) is one of the very few known single-phase multiferroic materials. While the bulk compound is rhombohedral (R), the discovery of an epitaxial strain-induced structural transition into a so-called "super tetragonal phase" (T-phase) in this material incited a flurry of research activity focused on gaining an understanding of this phase transition and its possible functionalities. This metastable phase of BiFeO3 is also multiferroic, with giant ferroelectric polarization and coexisting antiferromagnetic order, but above all it is the strain relaxation-induced phase mixtures and their outstanding piezoelectric and magnetoelectric responses which continue to intrigue and motivate the physicist and materials scientist communities. Here, we review the research into the T-phase and mixed-phase BiFeO3 system. We begin with a brief summary of the history of the T-phase and an analysis of the structure of the various phases reported in the literature. We then address important questions regarding the symmetry and octahedral rotation patterns and the (as yet underexplored) important role of chemistry in the formation of the metastable T-phase. We follow by describing the phase transitions in this material, and how these may hold promise for large magnetoelectric responses. Finally, we point out some experimental challenges inherent to the study of such a system, and potential pathways for how they may be overcome. It is our intention with this work to highlight important issues that, in our opinion, should be carefully considered by the community in order to use this fascinating materials system for a new paradigm of functionality. [ABSTRACT FROM AUTHOR]

Published

2016

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

Author

Sando, D., Bin Xu, Bellaiche, L., and Nagarajan, V.

Subjects

MULTIFERROIC materials, BISMUTH, FERRITES, HEMATITE, FERROELECTRIC materials

Abstract

Bismuth ferrite (BiFeO3) is one of the very few known single-phase multiferroic materials. While the bulk compound is rhombohedral (R), the discovery of an epitaxial strain-induced structural transition into a so-called "super tetragonal phase" (T-phase) in this material incited a flurry of research activity focused on gaining an understanding of this phase transition and its possible functionalities. This metastable phase of BiFeO3 is also multiferroic, with giant ferroelectric polarization and coexisting antiferromagnetic order, but above all it is the strain relaxation-induced phase mixtures and their outstanding piezoelectric and magnetoelectric responses which continue to intrigue and motivate the physicist and materials scientist communities. Here, we review the research into the T-phase and mixed-phase BiFeO3 system. We begin with a brief summary of the history of the T-phase and an analysis of the structure of the various phases reported in the literature. We then address important questions regarding the symmetry and octahedral rotation patterns and the (as yet underexplored) important role of chemistry in the formation of the metastable T-phase. We follow by describing the phase transitions in this material, and how these may hold promise for large magnetoelectric responses. Finally, we point out some experimental challenges inherent to the study of such a system, and potential pathways for how they may be overcome. It is our intention with this work to highlight important issues that, in our opinion, should be carefully considered by the community in order to use this fascinating materials system for a new paradigm of functionality. [ABSTRACT FROM AUTHOR]

Published

2016

4. Crafting the magnonic and spintronic response of BiFeO3 films by epitaxial strain.

Author

Sando, D., Agbelele, A., Rahmedov, D., Liu, J., Rovillain, P., Toulouse, C., Infante, I. C., Pyatakov, A. P., Fusil, S., Jacquet, E., Carrétéro, C., Deranlot, C., Lisenkov, S., Wang, D., Le Breton, J-M., Cazayous, M., Sacuto, A., Juraszek, J., Zvezdin, A. K., and Bellaiche, L.

Subjects

*MAGNONS, *SPINTRONICS, *BISMUTH compounds, *FERRITES, *EPITAXY, *CYCLOIDS, *ANTIFERROMAGNETISM

Abstract

Multiferroics are compounds that show ferroelectricity and magnetism. BiFeO3, by far the most studied, has outstanding ferroelectric properties, a cycloidal magnetic order in the bulk, and many unexpected virtues such as conductive domain walls or a low bandgap of interest for photovoltaics. Although this flurry of properties makes BiFeO3 a paradigmatic multifunctional material, most are related to its ferroelectric character, and its other ferroic property-antiferromagnetism-has not been investigated extensively, especially in thin films. Here we bring insight into the rich spin physics of BiFeO3 in a detailed study of the static and dynamic magnetic response of strain-engineered films. Using Mössbauer and Raman spectroscopies combined with Landau-Ginzburg theory and effective Hamiltonian calculations, we show that the bulk-like cycloidal spin modulation that exists at low compressive strain is driven towards pseudo-collinear antiferromagnetism at high strain, both tensile and compressive. For moderate tensile strain we also predict and observe indications of a new cycloid. Accordingly, we find that the magnonic response is entirely modified, with low-energy magnon modes being suppressed as strain increases. Finally, we reveal that strain progressively drives the average spin angle from in-plane to out-of-plane, a property we use to tune the exchange bias and giant-magnetoresistive response of spin valves. [ABSTRACT FROM AUTHOR]

Published

2013

5. Control of ferroelectricity and magnetism in multi-ferroic BiFeO3 by epitaxial strain.

Author

Sando, D., Agbelele, A., Daumont, C., Rahmedov, D., Ren, W., Infante, I. C., Lisenkov, S., Prosandeev, S., Fusil, S., Jacquet, E., Carrétéro, C., Petit, S., Cazayous, M., Juraszek, J., Le Breton, J.-M., Bellaiche, L., Dkhil, B., Barthélémy, A., and Bibes, M.

Subjects

*THIN films, *PEROVSKITE, *MAGNETISM, *FERROELECTRICITY, *MULTIFERROIC materials, *FERRITES, *TRANSITION temperature, *CURIE temperature

Abstract

Recently, strain engineering has been shown to be a powerful and flexible means of tailoring the properties of ABO3 perovskite thin films. The effect of epitaxial strain on the structure of the perovskite unit cell can induce a host of interesting effects, these arising from either polar cation shifts or rotation of the oxygen octahedra, or both. In the multi-ferroic perovskite bismuth ferrite (BiFeO3-BFO), both degrees of freedom exist, and thus a complex behaviour may be expected as one plays with epitaxial strain. In this paper, we review our results on the role of strain on the ferroic transition temperatures and ferroic order parameters. We find that, while the Néel temperature is almost unchanged by strain, the ferroelectric Curie temperature strongly decreases as strain increases in both the tensile and compressive ranges. Also unexpected is the very weak influence of strain on the ferroelectric polarization value. Using effective Hamiltonian calculations, we show that these peculiar behaviours arise from the competition between antiferrodistortive and polar instabilities. Finally, we present results on the magnetic order: while the cycloidal spin modulation present in the bulk survives in weakly strained films, it is destroyed at large strain and replaced by pseudo-collinear antiferromagnetic ordering. We discuss the origin of this effect and give perspectives for devices based on strain-engineered BiFeO3. [ABSTRACT FROM AUTHOR]

Published

2014