Structural, morphological and electrical properties of new type Dy doped Ca6-xNa2Y2(SiO4)6(OH)2 hydroxyapatite compound synthesized by co – precipitation method

IF 1.7 4区材料科学 Q2 MATERIALS SCIENCE, CERAMICS

Journal of Electroceramics Pub Date : 2022-01-03 DOI:10.1007/s10832-021-00274-3

Ananya Rout, Sadhana Agrawal

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引用次数: 4

Abstract

In this study Dy³⁺ doped Ca_6-xNa₂Y₂(SiO₄)₆(OH)₂ (x = 0 – 0.05 mol%) hydroxyapatite compound was synthesized by co – precipitation method. The structural analysis reveals that the prepared compound has single phase hexagonal structure with space group P6₃/m. Scanning electron microscopy images show that the grains have irregular morphology and the grain size lies between 120—800 nm. The dielectric and electrical conduction studies of hydroxyapatite compound was done over a wide range of frequency (10² – 10⁵ Hz) and temperature (50⁰C – 500⁰C) respectively. Dielectric measurement shows that orientational and space charge polarizations are the dominant polarization mechanisms. Complex impedance and electric modulus spectroscopy analysis shows that ionic conduction is the presiding conduction mechanism. Nyquist plots depict the contribution of grains rather than grain boundaries in the conduction phenomena. A.C conductivity analysis shows that hydroxyl (OH)⁻ and oxygen (O⁻²) ions were the main charge carriers responsible for conduction phenomena in hydroxyapatite compounds.

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共沉淀法合成新型Dy掺杂Ca6-xNa2Y2(SiO4)6(OH)2羟基磷灰石化合物的结构、形态和电性能

本文采用共沉淀法合成了Dy3+掺杂Ca6-xNa2Y2(SiO4)6(OH)2 (x = 0 ~ 0.05 mol%)羟基磷灰石化合物。结构分析表明，制备的化合物具有空间群为P63/m的单相六边形结构。扫描电镜图像显示，晶粒形貌不规则，晶粒尺寸在120 ~ 800 nm之间。羟基磷灰石化合物的介电和导电性研究分别在较宽的频率范围(102 ~ 105 Hz)和温度范围(500℃~ 5000C)下进行。介电测量表明，取向极化和空间极化是主要的极化机制。复阻抗和电模量谱分析表明，离子传导是主导的传导机制。奈奎斯特图描述了晶粒在传导现象中的贡献，而不是晶界。交流电导率分析表明，羟基(OH)−和氧(O−2)离子是羟基磷灰石化合物中导电现象的主要载流子。

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来源期刊

Journal of Electroceramics 工程技术-材料科学：硅酸盐

CiteScore

2.80

自引率

5.90%

发文量

审稿时长

5.7 months

期刊介绍： While ceramics have traditionally been admired for their mechanical, chemical and thermal stability, their unique electrical, optical and magnetic properties have become of increasing importance in many key technologies including communications, energy conversion and storage, electronics and automation. Electroceramics benefit greatly from their versatility in properties including: -insulating to metallic and fast ion conductivity -piezo-, ferro-, and pyro-electricity -electro- and nonlinear optical properties -feromagnetism. When combined with thermal, mechanical, and chemical stability, these properties often render them the materials of choice. The Journal of Electroceramics is dedicated to providing a forum of discussion cutting across issues in electrical, optical, and magnetic ceramics. Driven by the need for miniaturization, cost, and enhanced functionality, the field of electroceramics is growing rapidly in many new directions. The Journal encourages discussions of resultant trends concerning silicon-electroceramic integration, nanotechnology, ceramic-polymer composites, grain boundary and defect engineering, etc.