Optical and mechanical properties of compaction and slip cast processed transparent polycrystalline spinel ceramics

Transparent polycrystalline Magnesium Aluminate Spinel (MgAl2O4) specimens were formed by colloidal slip casting (SC) and uniaxial powder compaction (UDP) routes using powder with identical properties. SC and UDP formed specimens which were pressureless sintered and further subjected to hot isostati...

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Published inCeramics international Vol. 40; no. 4; pp. 5575 - 5581
Main Authors Ramavath, Pandu, Biswas, Papiya, Rajeswari, Kotikalapudi, Suresh, Madireddy Buchi, Johnson, Roy, Padmanabham, Gadhe, Kumbhar, Chandrashekhar Sadasiv, Chongdar, Tapas Kumar, Gokhale, Nitin Madhusudan
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.05.2014
Subjects
A. Hot isostatic pressing
C. Mechanical property
C. Optical property
Ceramics
Computer networks
D. Spinels
Fracture mechanics
Mechanical properties
Optical properties
Protocol (computers)
Slip casting
Spinel
C. Optical property
A. Hot isostatic pressing
C. Mechanical property
D. Spinels
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Abstract Transparent polycrystalline Magnesium Aluminate Spinel (MgAl2O4) specimens were formed by colloidal slip casting (SC) and uniaxial powder compaction (UDP) routes using powder with identical properties. SC and UDP formed specimens which were pressureless sintered and further subjected to hot isostatic pressing to eliminate the residual porosities and to achieve the transparency. SC samples exhibited better transmission compared to UDP samples. Mechanical properties were found to be lower by 10–15% for UDP samples and are complemented by the total fracture energy release rate (Jc) and JR–δ curves. Finally, the optical and mechanical properties were correlated with the processing routes.
AbstractList Transparent polycrystalline Magnesium Aluminate Spinel (MgAl2O4) specimens were formed by colloidal slip casting (SC) and uniaxial powder compaction (UDP) routes using powder with identical properties. SC and UDP formed specimens which were pressureless sintered and further subjected to hot isostatic pressing to eliminate the residual porosities and to achieve the transparency. SC samples exhibited better transmission compared to UDP samples. Mechanical properties were found to be lower by 10–15% for UDP samples and are complemented by the total fracture energy release rate (Jc) and JR–δ curves. Finally, the optical and mechanical properties were correlated with the processing routes.
Transparent polycrystalline magnesium aluminate spinel (MgAl2O4) specimens were formed by colloidal slip casting (SC) and uniaxial powder compaction (UDP) routes using powder with identical properties. The SC and UDP formed specimens were pressureless sintered and then hot isostatically pressed to eliminate residual porosity and achieve transparency. The SC samples exhibited better transmission compared to the UDP samples. Mechanical properties were lower by 10-15% for the UDP samples and were complemented by the total fracture energy release rate (Jc) and JR-delta curves. Finally, the optical and mechanical properties were correlated with the processing routes.
Author Ramavath, Pandu
Biswas, Papiya
Suresh, Madireddy Buchi
Padmanabham, Gadhe
Chongdar, Tapas Kumar
Rajeswari, Kotikalapudi
Kumbhar, Chandrashekhar Sadasiv
Gokhale, Nitin Madhusudan
Johnson, Roy
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Keywords C. Optical property
A. Hot isostatic pressing
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Snippet Transparent polycrystalline Magnesium Aluminate Spinel (MgAl2O4) specimens were formed by colloidal slip casting (SC) and uniaxial powder compaction (UDP)...
Transparent polycrystalline magnesium aluminate spinel (MgAl2O4) specimens were formed by colloidal slip casting (SC) and uniaxial powder compaction (UDP)...
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SubjectTerms A. Hot isostatic pressing
C. Mechanical property
C. Optical property
Ceramics
Computer networks
D. Spinels
Fracture mechanics
Mechanical properties
Optical properties
Protocol (computers)
Slip casting
Spinel
Title Optical and mechanical properties of compaction and slip cast processed transparent polycrystalline spinel ceramics
URI https://dx.doi.org/10.1016/j.ceramint.2013.10.149
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https://search.proquest.com/docview/1692381080
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