Cargando…
Piezoelectric Ceramics of the (1 − x)Bi(0.50)Na(0.50)TiO(3)–xBa(0.90)Ca(0.10)TiO(3) Lead-Free Solid Solution: Chemical Shift of the Morphotropic Phase Boundary, a Case Study for x = 0.06
Research and development of lead-free piezoelectric materials are still the hottest topics in the field of piezoelectricity. One of the most promising lead-free family of compounds to replace lead zirconate–titanate for actuators is that of Bi(0.50)Na(0.50)TiO(3) (BNT) based solid solutions. The pse...
| Autores principales: | , , , , , , |
|---|---|
| Formato: | Online Artículo Texto |
| Lenguaje: | English |
| Publicado: |
MDPI
2017
|
| Materias: | |
| Acceso en línea: | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5551779/ https://www.ncbi.nlm.nih.gov/pubmed/28773096 http://dx.doi.org/10.3390/ma10070736 |
| _version_ | 1783256352933543936 |
|---|---|
| author | Vivar-Ocampo, Rodrigo Pardo, Lorena Ávila, David Morán, Emilio González, Amador M. Bucio, Lauro Villafuerte-Castrejón, María-Elena |
| author_facet | Vivar-Ocampo, Rodrigo Pardo, Lorena Ávila, David Morán, Emilio González, Amador M. Bucio, Lauro Villafuerte-Castrejón, María-Elena |
| author_sort | Vivar-Ocampo, Rodrigo |
| collection | PubMed |
| description | Research and development of lead-free piezoelectric materials are still the hottest topics in the field of piezoelectricity. One of the most promising lead-free family of compounds to replace lead zirconate–titanate for actuators is that of Bi(0.50)Na(0.50)TiO(3) (BNT) based solid solutions. The pseudo-binary (1 − x)Bi(0.50)Na(0.50)TiO(3)–xBa(1 − y)Ca(y)TiO(3) system has been proposed for high temperature capacitors and not yet fully explored as piezoelectric material. In this work, the solid solution with x = 0.06 and y = 0.10 was obtained by two different synthesis routes: solid state and Pechini, aiming at using reduced temperatures, both in synthesis (<800 °C) and sintering (<1150 °C), while maintaining appropriated piezoelectric performance. Crystal structure, ceramic grain size, and morphology depend on the synthesis route and were analyzed by X-ray diffraction, together with scanning and transmission electron microscopy. The effects of processing and ceramic microstructure on the structural, dielectric, ferroelectric, and piezoelectric properties were discussed in terms of a shift of the Morphotropic Phase Boundary, chemically induced by the synthesis route. |
| format | Online Article Text |
| id | pubmed-5551779 |
| institution | National Center for Biotechnology Information |
| language | English |
| publishDate | 2017 |
| publisher | MDPI |
| record_format | MEDLINE/PubMed |
| spelling | pubmed-55517792017-08-11 Piezoelectric Ceramics of the (1 − x)Bi(0.50)Na(0.50)TiO(3)–xBa(0.90)Ca(0.10)TiO(3) Lead-Free Solid Solution: Chemical Shift of the Morphotropic Phase Boundary, a Case Study for x = 0.06 Vivar-Ocampo, Rodrigo Pardo, Lorena Ávila, David Morán, Emilio González, Amador M. Bucio, Lauro Villafuerte-Castrejón, María-Elena Materials (Basel) Article Research and development of lead-free piezoelectric materials are still the hottest topics in the field of piezoelectricity. One of the most promising lead-free family of compounds to replace lead zirconate–titanate for actuators is that of Bi(0.50)Na(0.50)TiO(3) (BNT) based solid solutions. The pseudo-binary (1 − x)Bi(0.50)Na(0.50)TiO(3)–xBa(1 − y)Ca(y)TiO(3) system has been proposed for high temperature capacitors and not yet fully explored as piezoelectric material. In this work, the solid solution with x = 0.06 and y = 0.10 was obtained by two different synthesis routes: solid state and Pechini, aiming at using reduced temperatures, both in synthesis (<800 °C) and sintering (<1150 °C), while maintaining appropriated piezoelectric performance. Crystal structure, ceramic grain size, and morphology depend on the synthesis route and were analyzed by X-ray diffraction, together with scanning and transmission electron microscopy. The effects of processing and ceramic microstructure on the structural, dielectric, ferroelectric, and piezoelectric properties were discussed in terms of a shift of the Morphotropic Phase Boundary, chemically induced by the synthesis route. MDPI 2017-07-01 /pmc/articles/PMC5551779/ /pubmed/28773096 http://dx.doi.org/10.3390/ma10070736 Text en © 2017 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/). |
| spellingShingle | Article Vivar-Ocampo, Rodrigo Pardo, Lorena Ávila, David Morán, Emilio González, Amador M. Bucio, Lauro Villafuerte-Castrejón, María-Elena Piezoelectric Ceramics of the (1 − x)Bi(0.50)Na(0.50)TiO(3)–xBa(0.90)Ca(0.10)TiO(3) Lead-Free Solid Solution: Chemical Shift of the Morphotropic Phase Boundary, a Case Study for x = 0.06 |
| title | Piezoelectric Ceramics of the (1 − x)Bi(0.50)Na(0.50)TiO(3)–xBa(0.90)Ca(0.10)TiO(3) Lead-Free Solid Solution: Chemical Shift of the Morphotropic Phase Boundary, a Case Study for x = 0.06 |
| title_full | Piezoelectric Ceramics of the (1 − x)Bi(0.50)Na(0.50)TiO(3)–xBa(0.90)Ca(0.10)TiO(3) Lead-Free Solid Solution: Chemical Shift of the Morphotropic Phase Boundary, a Case Study for x = 0.06 |
| title_fullStr | Piezoelectric Ceramics of the (1 − x)Bi(0.50)Na(0.50)TiO(3)–xBa(0.90)Ca(0.10)TiO(3) Lead-Free Solid Solution: Chemical Shift of the Morphotropic Phase Boundary, a Case Study for x = 0.06 |
| title_full_unstemmed | Piezoelectric Ceramics of the (1 − x)Bi(0.50)Na(0.50)TiO(3)–xBa(0.90)Ca(0.10)TiO(3) Lead-Free Solid Solution: Chemical Shift of the Morphotropic Phase Boundary, a Case Study for x = 0.06 |
| title_short | Piezoelectric Ceramics of the (1 − x)Bi(0.50)Na(0.50)TiO(3)–xBa(0.90)Ca(0.10)TiO(3) Lead-Free Solid Solution: Chemical Shift of the Morphotropic Phase Boundary, a Case Study for x = 0.06 |
| title_sort | piezoelectric ceramics of the (1 − x)bi(0.50)na(0.50)tio(3)–xba(0.90)ca(0.10)tio(3) lead-free solid solution: chemical shift of the morphotropic phase boundary, a case study for x = 0.06 |
| topic | Article |
| url | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5551779/ https://www.ncbi.nlm.nih.gov/pubmed/28773096 http://dx.doi.org/10.3390/ma10070736 |
| work_keys_str_mv | AT vivarocamporodrigo piezoelectricceramicsofthe1xbi050na050tio3xba090ca010tio3leadfreesolidsolutionchemicalshiftofthemorphotropicphaseboundaryacasestudyforx006 AT pardolorena piezoelectricceramicsofthe1xbi050na050tio3xba090ca010tio3leadfreesolidsolutionchemicalshiftofthemorphotropicphaseboundaryacasestudyforx006 AT aviladavid piezoelectricceramicsofthe1xbi050na050tio3xba090ca010tio3leadfreesolidsolutionchemicalshiftofthemorphotropicphaseboundaryacasestudyforx006 AT moranemilio piezoelectricceramicsofthe1xbi050na050tio3xba090ca010tio3leadfreesolidsolutionchemicalshiftofthemorphotropicphaseboundaryacasestudyforx006 AT gonzalezamadorm piezoelectricceramicsofthe1xbi050na050tio3xba090ca010tio3leadfreesolidsolutionchemicalshiftofthemorphotropicphaseboundaryacasestudyforx006 AT buciolauro piezoelectricceramicsofthe1xbi050na050tio3xba090ca010tio3leadfreesolidsolutionchemicalshiftofthemorphotropicphaseboundaryacasestudyforx006 AT villafuertecastrejonmariaelena piezoelectricceramicsofthe1xbi050na050tio3xba090ca010tio3leadfreesolidsolutionchemicalshiftofthemorphotropicphaseboundaryacasestudyforx006 |