Grain Boundary Segregation-Induced Phase Transformation and Grain Growth in Y2O3-Stabilized ZrO2 Polycrystals

Koji Matsui; Hidehiro Yoshida; Yuichi Ikuhara

doi:10.4028/www.scientific.net/KEM.616.8

Paper Titles

Preface, Committees and Sponsors

Synthesis and Characterization of Hafnium Carbide Based Ceramics
p.1

Grain Boundary Segregation-Induced Phase Transformation and Grain Growth in Y₂O₃-Stabilized ZrO₂ Polycrystals
p.8

A Model for Estimating Internal Stress during Sintering of Ceramic Multiphase Laminates
p.14

Fabrication of Nitride Ceramics by Electric Current Assisted Sintering
p.19

Effect of Initial Alpha-SiC Content on Thermal Conductivity of Silicon Carbide Ceramics
p.23

Fabrication of Carbon Nanotube Reinforced Boron Carbide Composite by Hot-Pressing Following Extrusion Molding
p.27

Consolidation of SiC Powder Coated with SiO₂ Nanolayer by Spark Plasma Sintering
p.32

High-Speed Deposition of SiC Thick Film by Halide Precursor
p.37

HomeKey Engineering MaterialsKey Engineering Materials Vol. 616Grain Boundary Segregation-Induced Phase...

Grain Boundary Segregation-Induced Phase Transformation and Grain Growth in Y₂O₃-Stabilized ZrO₂ Polycrystals

Abstract:

We systematically investigated the phase transformation and grain-growth behaviors during sintering in 2 and 3 mol% Y₂O₃-stabilized tetragonal ZrO₂ (2Y and 3Y) and 8 mol% Y₂O₃-stabilized cubic ZrO₂ polycrystals (8Y). In particular, grain-boundary segregation and grain-interior distribution of Y³⁺ ions were examined by high-resolution transmission electron microscopy (HRTEM)- and scanning transmission electron microscopy (STEM)-nanoprobe X-ray energy dispersive spectroscopy (EDS) techniques. Above 1200°C, grain growth during sintering in 8Y was much faster than that in 2Y and 3Y. In the grain boundaries in these specimens, amorphous layers did not present; however, Y³⁺ ions segregated at the grain boundaries over a width of about 10 nm. The amount of segregated Y³⁺ ions in 8Y was significantly less than in 2Y and 3Y. This indicates that the amount of segregated Y³⁺ ions is related to grain growth behavior; i.e., an increase in segregated Y³⁺ ions retards grain growth. Therefore, grain-growth behavior during sintering can be reasonably explained by the solute-drag mechanism of Y³⁺ ions segregating along the grain boundary. In 2Y and 3Y, the cubic-phase regions were formed in grain interiors adjacent to the grain boundaries and/or the multiple junctions in which Y³⁺ ions segregated, which can be explained by a grain boundary segregation-induced phase transformation (GBSIPT) mechanism.

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Key Engineering Materials (Volume 616)

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8-13

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.616.8

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Online since:

June 2014

Authors:

Koji Matsui*, Hidehiro Yoshida, Yuichi Ikuhara

Keywords:

Grain Boundary Segregation-Induced Phase Transformation, Grain Growth, Grain-Boundary Segregation, Microstructure, Sintering, YSZ

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