Bioactive potassium and sodium niobate (K0.5Na0.5)NbO3 synthesized by solid‐state reaction and sol–gel methods

Bioactive potassium and sodium niobate (K0.5Na0.5)NbO3 synthesized by solid‐state reaction and sol–gel methods

This study proposes an innovative approach in the quest for piezoelectric materials, aiming to replace lead‐based ceramics (PZTs), known for their high toxicity. Potassium sodium niobate (KNN) compounds were chosen as a promising alternative. While the synthesis of KNN via solid‐state reaction (SSR)...

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Bibliographic Details
Published in:International journal of applied ceramic technology Vol. 21; no. 3; pp. 1408 - 1424
Main Authors: Noronha Ferreira Ribeiro, Suzana, Elzubair Eltom, Amal, Marçal, Rubens Lincoln Santana Blazutti, Navarro Da Rocha, Daniel, Cationi Hirata, Mariáh, Domingos Mariano, Eric, Machado, Izabel Fernanda, Prado Da Silva, Marcelo Henrique
Format: Journal Article
Language:English
Published: Malden Wiley Subscription Services, Inc 01-05-2024
Subjects:
Apatite
bioactivity
Bioceramics
Biocompatibility
Biological activity
Crystal structure
Densification
Density
Niobates
perovskites
piezoelectric materials
Piezoelectricity
Plasma sintering
Potassium
Sodium compounds
Sol-gel processes
sol–gel
Spark plasma sintering
spark plasma sintering (SPS)
Stoichiometry
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Summary:This study proposes an innovative approach in the quest for piezoelectric materials, aiming to replace lead‐based ceramics (PZTs), known for their high toxicity. Potassium sodium niobate (KNN) compounds were chosen as a promising alternative. While the synthesis of KNN via solid‐state reaction (SSR) is common, maintaining the correct stoichiometry is challenging. In this work, we employed sol–gel (SG) and SSR methods for synthesis, combined with both conventional sintering techniques and spark plasma sintering. Comprehensive analyses were conducted, including crystal structure, microstructure, density, and piezoelectric properties, as well as bioactivity tests, among others. The results revealed that KNN samples exhibited remarkable piezoelectricity, coupled with surprising bioactivity, demonstrating good cell viability and resorption in a biological medium. Thoughtful selection of synthesis methods and variations in the sintering process were crucial in achieving high densification rates, enabling the investigation of the interplay between density and piezoelectric properties. Additionally, the application of polarization prior to immersion in a biological medium stimulated apatite precipitation. This indicates the promising application of these compounds as bioceramic devices.
ISSN:1546-542X
1744-7402
DOI:10.1111/ijac.14656