Polymorphism in Micro-, Submicro-, and Nanocrystalline NaNbO<sub>3</sub>

Shiratori, Yosuke; Magrez, Arnaud; Dornseiffer, Jiirgen; Haegel, Franz‐Hubert; Pithan, Christian; Waser, Rainer

doi:10.1021/jp052974p

Cited by 115 publications

(122 citation statements)

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“…[31][32][33][34][35][36] In spite of the extensive experimental 4-30 and theoretical 31 -36 studies, there are numerous controversies surrounding the phase diagram of NaNbO 3 with conflicting reports in the literature 29 on the existence of ferroelectric orde ring at low temperature. Recent x-ray diffraction and Raman spectroscopic studies suggest that the observation of noncentrosymmetric ferroelectric phases in NaNbO 3 is strongly influenced by the particle size 37 , but these are again not clearly understood. As m aterial properties are strongly influenced by the associated crystal structure, a ccurate characterization of the phase diagram of NaNbO 3 is essential for design of new sodium niobate based ceramics for applications.…”

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confidence: 99%

Competing antiferroelectric and ferroelectric interactions inNaNbO3: Neutron diffraction and theoretical studies

et al. 2007

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Neutron diffraction studies using powder samples have been used to understand the complex sequence of low temperature phase transitions of NaNbO3 in the temperature range from 12 K-350 K. Detailed Rietveld analysis of the diffraction data reveal that the antiferroelectric to ferroelectric phase transition occurs on cooling around 73 K while the reverse ferroelectric to antiferroelectric transition occurs on heating at 245 K. However, the former transformation is not complete till down to 12 K and there is unambiguous evidence for the presence of the ferroelectric R3c phase coexisting with an antiferroelectic phase (Pbcm) over a wide range of temperatures. The coexisting phases and reported anomalous smearing of the dielectric response akin to dipole glasses and relaxors observed in the same temperature range are consistent with competing ferroelectric and antiferroelectric interactions in NaNbO 3 . We have carried out theoretical lattice dynamical calculations which reveal that the free energies of the antiferroelectric Pbcm and ferroelectric R3c phases are nearly identical over a wide range of temperature. The small energy difference between the two phases is of interest as it explains the observed coexistence of these phases over a wide range of temperature. The computed double well depths and energy barriers from paraelectric Pm 3m to antiferroelectric Pbcm and ferroelectric R3c phases in NaNbO 3 are also quite similar, although the ferroelectric R3c phase has a slightly lower energy.

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Competing antiferroelectric and ferroelectric interactions inNaNbO3: Neutron diffraction and theoretical studies

et al. 2007

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“…It should be noted in any case that all samples contain different fractions of these ultrafine NaNbO 3 grains, which are believed to crystallize in the new polymorph Pmc2 1 because of their small size. 12 The lamellar substructure could be explained through the formation of ferroelastic or ferroelectric domains, since in this crystal structure the center of inversion, which is normally observed in bulk coarse NaNbO 3 is absent. The exact nature and the origin of the substructure and the lamellae, however, are still unclear and need further detailed studies, e.g.…”

Section: Results and Discussion 31 Ceramic Processing And Consolidationmentioning

confidence: 86%

“…One should note that the structure with Pmma space group is stable for a particle size below 70 nm while the submicron structure Pmc2 1 is stable when the particle size is below 600 nm. 12 In XRPD patterns, the two structures can be distinguished by the splitting of the 022 220 reflections 2uŋ40c as well as by the position of the 201 102 peaks 2uŋ36.1c for the Pmc2 1 structure and 2uŋ36.4c for the Pmma structure . According to these remarks, one can conclude that the sinterforged sample is mainly composed of submicron sized grains.…”

Section: Crystallographic Analysismentioning

confidence: 99%

“…Recently we reported on a new polar polymorph in pure ultra-fine particles of NaNbO 3 -powders 12 showing enhanced piezoactivity compared to coarse particles of the same composition 13 due to the stabilization of a noncentrosymmetric crystal structure. Coarse NaNbO 3 is known to crystallize in the orthorhombic space group Pbcm, 14 which is not polar due to the presence of an inversion centre in the unit cell of the lattice.…”

Section: Introductionmentioning

confidence: 99%

“…Basically the results from XRD and Raman spectroscopy for the present ceramics indicated good agreement with those for powders. 12 To clarify phase stabilization mechanisms, difference of surface properties, which is attributed to the presenceabsence of grain boundaries, should be also taken into consideration.…”

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Consolidation, Microstructure and Crystallography of Dense NaNbO<sub>3</sub> Ceramics with Ultra-Fine Grain Size

Pithan¹,

Shiratori²,

Magrez

et al. 2006

J. Ceram. Soc. Japan

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Paper péÉÅá~ä fëëìÉ Äó dìÉëí bÇáíçêë aÉÇáÅ~íÉÇ íç mêçÑK d äìåíÉê mÉíòçïW jçÇÉêå qêÉåÇë áå^Çî~åÅÉÇ`Éê~ãáÅë çåëçäáÇ~íáçå, jáÅêçëíêìÅíìêÉ~åÇ`êóëí~ääçÖê~éÜó çÑ aÉåëÉ k~kÄl P Éê~ãáÅë ïáíÜ räíê~cáåÉ dê~áå páòÉ The present study reports on the preparation and structural characterization of dense NaNbO 3 ceramics with ultrafine grain size. Nanocrystalline raw powders obtained via microemulsion mediated synthesis were consolidated to green compacts, sinterforged to ceramic pellets with high density and ultra-fine microstructure and finally annealed under different thermal regimes in order to systematically increase the average grain size in the range from several hundreds of nm up to a few mm. Structural characterization of these materials included electron-microscopic observation and X-ray diffraction in combination with temperature tuning Raman-spectroscopy in order to detect both the global and local crystallographic symmetry in dependence of the grain size. The results show that ceramics with an average grain size from approximately 360 nm to 1-2 mm consist of a phase mixture of the anti-ferroelectric phase with the space group Pbcm, which is also observed for the conventional case of coarse NaNbO 3 , and secondly of a new polar polymorph described by the space group Pmc2 1 . The volume fraction of the second polar modification appears to increase with decreasing grain size suggesting an enhancement of the piezoelectric response of ultra-fine grained NaNbO 3 ceramics in comparison to coarse grained material of the same composition.

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Polar Oxide Nanopowders Prepared by Mechanical Treatments

Koruza

Rojac

Malič

2015

Handbook of Mechanical Nanostructuring

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Polymorphism in Micro-, Submicro-, and Nanocrystalline NaNbO₃

Cited by 115 publications

References 34 publications

Competing antiferroelectric and ferroelectric interactions inNaNbO3: Neutron diffraction and theoretical studies

Competing antiferroelectric and ferroelectric interactions inNaNbO3: Neutron diffraction and theoretical studies

Consolidation, Microstructure and Crystallography of Dense NaNbO<sub>3</sub> Ceramics with Ultra-Fine Grain Size

Polar Oxide Nanopowders Prepared by Mechanical Treatments

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Polymorphism in Micro-, Submicro-, and Nanocrystalline NaNbO3

Cited by 115 publications

References 34 publications

Competing antiferroelectric and ferroelectric interactions inNaNbO3: Neutron diffraction and theoretical studies

Competing antiferroelectric and ferroelectric interactions inNaNbO3: Neutron diffraction and theoretical studies

Consolidation, Microstructure and Crystallography of Dense NaNbO<sub>3</sub> Ceramics with Ultra-Fine Grain Size

Polar Oxide Nanopowders Prepared by Mechanical Treatments

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Polymorphism in Micro-, Submicro-, and Nanocrystalline NaNbO₃