Electric-field-induced redistribution of polar nano-regions in a relaxor ferroelectric

Xu, Guangyong; Zhong, Z.; Bing, Yonghong; Ye, Z.-G.; Shirane, G.

doi:10.1038/nmat1560

Cited by 293 publications

(213 citation statements)

References 40 publications

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“…The presence of polar domains in the cubic phases of relaxors, where they are nominally forbidden, may be caused by flexoelectricity and internal strains due to local nonstoichiometry (Ahn et al, 2003). When mixed with ordinary ferroelectrics such as PbTiO 3 , or subjected to applied fields E, these nanodomains increase in size to become macroscopic (Mulvihill, Cross, and Uchino, 1995;Xu et al, 2006). As for the shape of the domains, in pure PbZn 1=3 Nb 2=3 O 3 (PZN), the domain walls may be spindlelike (Mulvihill, Cross, and Uchino, 1995) or dendritic (Liu, 2004) but become increasing lamellar with increasing additions of PbTiO 3 .…”

Section: G Nanodomains In Bulkmentioning

confidence: 99%

Domain wall nanoelectronics

et al. 2012

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Domains in ferroelectrics were considered to be well understood by the middle of the last century: They were generally rectilinear, and their walls were Ising-like. Their simplicity stood in stark contrast to the more complex Bloch walls or Néel walls in magnets. Only within the past decade and with the introduction of atomic-resolution studies via transmission electron microscopy, electron holography, and atomic force microscopy with polarization sensitivity has their real complexity been revealed. Additional phenomena appear in recent studies, especially of magnetoelectric materials, where functional properties inside domain walls are being directly measured. In this paper these studies are reviewed, focusing attention on ferroelectrics and multiferroics but making comparisons where possible with magnetic domains and domain walls. An important part of this review will concern device applications, with the spotlight on a new paradigm of ferroic devices where the domain walls, rather than the domains, are the active element. Here magnetic wall microelectronics is already in full swing, owing largely to the work of Cowburn and of Parkin and their colleagues. These devices exploit the high domain wall mobilities in magnets and their resulting high velocities, which can be supersonic, as shown by Kreines' and co-workers 30 years ago. By comparison, nanoelectronic devices employing ferroelectric domain walls often have slower domain wall speeds, but may exploit their smaller size as well as their different functional properties. These include domain wall conductivity (metallic or even superconducting in bulk insulating or semiconducting oxides) and the fact that domain walls can be ferromagnetic while the surrounding domains are not.

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Section: G Nanodomains In Bulkmentioning

confidence: 99%

Domain wall nanoelectronics

et al. 2012

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“…[12][13][14][15][16] These PNR have been linked to the unique anisotropic and temperature-dependent x-ray and neutron diffuse scattering patterns that have been observed in lead-based RFs. [17][18][19][20][21][22][23][24] For example, in the (HK0) scattering plane, the elastic diffuse scattering intensity forms butterfly-shaped contours near reciprocal lattice vectors of the form (h00) that feature prominent ridges that extend along [110] and [110], while the corresponding contours near (hh0) are ellipsoidal insofar as only a single ridge oriented along [110] is seen. In general, the contours near all reciprocal lattice points in the (HK0) scattering plane exhibit ridges that extend along one or more of the 110 directions.…”

Section: Introductionmentioning

confidence: 99%

Lead-free and lead-basedABO3perovskite relaxors with mixed-valenceA-site and
Ge
¹
,
Devreugd
²
,
Phelan
³

et al. 2013
Phys. Rev. B
62
4
49
0
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We report the results of neutron elastic-scattering measurements made between − 250• C and 620• C on the lead-free relaxor (Na 1/2 Bi 1/2 )TiO 3 (NBT). Strong, anisotropic, elastic diffuse scattering intensity decorates the (100), (110), (111), (200), (210), and (220) Bragg peaks at room temperature. The wave-vector dependence of this diffuse scattering is compared to that in the lead-based relaxor Pb(Mg 1/3 Nb 2/3 )O 3 (PMN) to determine if any features might be common to relaxors. Prominent ridges in the elastic diffuse scattering intensity contours that extend along 110 are seen that exhibit the same zone dependence as those observed in PMN and other lead-based relaxors. These ridges disappear gradually on heating above the cubic-to-tetragonal phase transition temperature T CT = 523• C, which is also near the temperature at which the dielectric permittivity begins to deviate from Curie-Weiss behavior. We thus identify the 110 -oriented ridges as a relaxor-specific property. The diffuse scattering contours also display narrower ridges oriented along 100 that are consistent with the x-ray results of Kreisel et al. [Phys. Rev. B 68, 014113 (2003)]; these vanish near 320• C, indicating that they have a different physical origin. The 100 -oriented ridges are not observed in PMN. We observe no equivalent relaxorspecific elastic diffuse scattering from the homovalent relaxor analogues K 0.95 Li 0.05 TiO 3 (A-site disordered) and KTa 0.95 Nb 0.05 O 3 (B-site disordered). This suggests that the 110 -oriented diffuse scattering ridges are correlated with the presence of strong random electric fields and invites a reassessment of what defines the relaxor phase. We find that doping NBT with 5.6% BaTiO 3 , a composition close to the morphotropic phase boundary with enhanced piezoelectric properties, increases the room-temperature correlation length along ) superlattice reflection associated with the Cc space group based on the atomic coordinates published in the x-ray study by Aksel et al. [Appl. Phys. Lett. 98, 152901 (2011)] for NBT. We show that a skin effect, analogous to that reported in the relaxors PZN-xPT and PMN-xPT, can reconcile our neutron single-crystal data with the x-ray powder data of Aksel et al. [Appl. Phys. Lett. 98, 152901 (2011)]. Our finding of a skin effect in a lead-free, A-site disordered, heterovalent relaxor supports the idea that it arises in the presence of strong random electric fields.

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“…17 The difference in the diffuse features of the two systems originates in the nature of the polarization; the polarization of the lead-containing materials is accompanied by a distortion of the unit cell and subsequent domain formation, whereas the polarization in BNT-BT occurs together with octahedral tilts that double the unit cell. Therefore, diffuse streaking due to the nanoregions in BNT-BT shows up at half order reflections.…”

mentioning

confidence: 99%

Structural origins of relaxor behavior in a 0.96(Bi1/2Na1/2)TiO3–0.04BaTiO3 single crystal under electric field

Daniels

Rödel

et al. 2011

Applied Physics Letters

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Diffuse x-ray scattering intensities from a single crystal of 0.96(Bi1/2Na1/2TiO3)–0.04(BaTiO3) have been collected at room temperature with and without application of an electric field along the [100] direction. Distinct features in the diffuse scattering intensities indicate correlations on a nanometer length scale. It is shown that locally correlated planar-like structures and octahedral tilt-domains within the room temperature rhombohedral R3c phase are both electrically active and are irreversibly affected by application of an electric field of 4.3 kV/mm. The field dependence of these nanoscale structures is correlated with the relaxor behavior of the material by macroscopic permittivity measurements.

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Electric-field-induced redistribution of polar nano-regions in a relaxor ferroelectric

Cited by 293 publications

References 40 publications

Domain wall nanoelectronics

Domain wall nanoelectronics

Lead-free and lead-basedABO3perovskite relaxors with mixed-valenceA-site and
Ge
¹
,
Devreugd
²
,
Phelan
³

et al. 2013
Phys. Rev. B
62
4
49
0
View full text Add to dashboard Cite

Structural origins of relaxor behavior in a 0.96(Bi1/2Na1/2)TiO3–0.04BaTiO3 single crystal under electric field

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Electric-field-induced redistribution of polar nano-regions in a relaxor ferroelectric

Cited by 293 publications

References 40 publications

Domain wall nanoelectronics

Domain wall nanoelectronics

Lead-free and lead-basedABO3perovskite relaxors with mixed-valenceA-site andGe1, Devreugd2, Phelan3 et al. 2013Phys. Rev. B624490View full textAdd to dashboardCite

Structural origins of relaxor behavior in a 0.96(Bi1/2Na1/2)TiO3–0.04BaTiO3 single crystal under electric field

Contact Info

Product

Resources

About

Lead-free and lead-basedABO3perovskite relaxors with mixed-valenceA-site and
Ge
¹
,
Devreugd
²
,
Phelan
³

et al. 2013
Phys. Rev. B
62
4
49
0
View full text Add to dashboard Cite