Synthesis of zirconia microcrystals by hydrothermal method

Synthesis of zirconia microcrystals by hydrothermal method

A major drawback to the practical application of shape memory ceramics (SMCs) is the limited amount of strain it can sustain before cracking. This cracking is due to the large mismatch stresses between neighbouring grains that result due to the phase transformation in polycrystalline ceramics. In or...

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Main Author: Chen, Kenbin
Other Authors: Gan Chee Lip
Format: Final Year Project
Language:English
Published: 2015
Subjects:
DRNTU::Engineering::Materials::Ceramic materials
Online Access:http://hdl.handle.net/10356/64677
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-646772023-03-04T15:34:09Z Synthesis of zirconia microcrystals by hydrothermal method Chen, Kenbin Gan Chee Lip School of Materials Science and Engineering Temasek Laboratories DRNTU::Engineering::Materials::Ceramic materials A major drawback to the practical application of shape memory ceramics (SMCs) is the limited amount of strain it can sustain before cracking. This cracking is due to the large mismatch stresses between neighbouring grains that result due to the phase transformation in polycrystalline ceramics. In order to reduce these stresses, the size scale of the sample as well as the unstable grain boundary regions have to be minimized. This report serves to investigate the effectiveness of hydrothermal synthesis in producing fine scaled zirconia micro/nano-particles. For this study, 0.5M zirconyl nitrate hydrate and 5M sodium hydroxide were chosen as precursor materials and synthesized at 200°C. Hydrothermal medium composition and time parameters were varied to study their corresponding effects on zirconia particle morphology, shape and size. This project aims to ascertain the optimal conditions of hydrothermal synthesis so as to achieve zirconia particles of small volume structures, 500 nm to 1 µm in length with uniform aspect ratios. Yttrium nitrate additives were also varied at 3, 4 and 10 mol% to determine the ideal mole percentage for stabilization of the tetragonal zirconia phase. It was found that the sample with the reagent composition of 1:3, synthesized for 24 hours and an addition of 10 mol% yttria yielded rice grain like particles (525 x 180 nm) with tetragonal composition of 39.9 wt%. Theoretically, these dimensions are small enough to sufficiently eliminate the mismatch stresses. However, further study is needed to refine the hydrothermal process in order to attain complete phase stabilization and consequently, achieve superelastic properties in the ceramic. A thorough examination with reported results on the effects of the aforementioned experimental conditions on morphology as well as that of the additives on the phase stabilization of zirconia nanocrystals will be discussed at length. Bachelor of Engineering (Materials Engineering) 2015-05-29T05:04:15Z 2015-05-29T05:04:15Z 2015 2015 Final Year Project (FYP) http://hdl.handle.net/10356/64677 en Nanyang Technological University 48 p. application/pdf
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic DRNTU::Engineering::Materials::Ceramic materials
spellingShingle DRNTU::Engineering::Materials::Ceramic materials
Chen, Kenbin
Synthesis of zirconia microcrystals by hydrothermal method
description A major drawback to the practical application of shape memory ceramics (SMCs) is the limited amount of strain it can sustain before cracking. This cracking is due to the large mismatch stresses between neighbouring grains that result due to the phase transformation in polycrystalline ceramics. In order to reduce these stresses, the size scale of the sample as well as the unstable grain boundary regions have to be minimized. This report serves to investigate the effectiveness of hydrothermal synthesis in producing fine scaled zirconia micro/nano-particles. For this study, 0.5M zirconyl nitrate hydrate and 5M sodium hydroxide were chosen as precursor materials and synthesized at 200°C. Hydrothermal medium composition and time parameters were varied to study their corresponding effects on zirconia particle morphology, shape and size. This project aims to ascertain the optimal conditions of hydrothermal synthesis so as to achieve zirconia particles of small volume structures, 500 nm to 1 µm in length with uniform aspect ratios. Yttrium nitrate additives were also varied at 3, 4 and 10 mol% to determine the ideal mole percentage for stabilization of the tetragonal zirconia phase. It was found that the sample with the reagent composition of 1:3, synthesized for 24 hours and an addition of 10 mol% yttria yielded rice grain like particles (525 x 180 nm) with tetragonal composition of 39.9 wt%. Theoretically, these dimensions are small enough to sufficiently eliminate the mismatch stresses. However, further study is needed to refine the hydrothermal process in order to attain complete phase stabilization and consequently, achieve superelastic properties in the ceramic. A thorough examination with reported results on the effects of the aforementioned experimental conditions on morphology as well as that of the additives on the phase stabilization of zirconia nanocrystals will be discussed at length.
author2 Gan Chee Lip
author_facet Gan Chee Lip
Chen, Kenbin
format Final Year Project
author Chen, Kenbin
author_sort Chen, Kenbin
title Synthesis of zirconia microcrystals by hydrothermal method
title_short Synthesis of zirconia microcrystals by hydrothermal method
title_full Synthesis of zirconia microcrystals by hydrothermal method
title_fullStr Synthesis of zirconia microcrystals by hydrothermal method
title_full_unstemmed Synthesis of zirconia microcrystals by hydrothermal method
title_sort synthesis of zirconia microcrystals by hydrothermal method
publishDate 2015
url http://hdl.handle.net/10356/64677
_version_ 1759854623906070528

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