Paper Titles

Preface, Committees and Sponsors

Thoughts on Superplasticity in General and on its Role in Earth Deformation
p.3

Development of High-Strain-Rate Superplastic Oxide Ceramics Based on Flow Mechanism
p.9

Grain Boundary Sliding during Low Temperature Creep of Ultrafine and Coarse Grained Aluminum
p.17

On the Controversy about the Presence of Grain Boundary Sliding in Mg AZ31
p.22

Common Mechanism for Superplastic Deformation in Different Classes of Materials
p.26

Slip Induced Strain Rate Sensitivity for Superplastic Material?
p.31

EBSD Study of Microstructural Development during Superplastic-Like Forming
p.37

Characteristics of the GBS – SDC Transition during Bi-Axial Forming of AA5083
p.43

HomeMaterials Science ForumMaterials Science Forum Vol. 735Development of High-Strain-Rate Superplastic Oxide...

Development of High-Strain-Rate Superplastic Oxide Ceramics Based on Flow Mechanism

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Abstract:

In order to attain high-strain-rate superplasticity (HSRS) in ceramics, flow behavior was examined with ZrO₂ reference sample. The results suggest that the enhancement of the accommodation processes of grain boundary sliding (GBS) is important in addition to the careful controlling the microstructural factors, such as stable fine grain structure, reducing residual pores and so on. The spinel particles dispersion can simultaneously provide the following positive factors to ZrO₂: i) suppressed grain growth due to pinning effect of spinel particles, enhanced accommodation due to ii) accelerated relaxation of stress concentrations exerted by GBS through dislocation motion and iii) accelerated lattice diffusion caused by the dissolution of aluminum and magnesium into ZrO₂ from the spinel particles. The positive factors due to spinel dispersion make it possible to attain HSRS in ZrO₂ ceramics.

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Superplasticity in Advanced Materials - ICSAM 2012

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Periodical:

Materials Science Forum (Volume 735)

Pages:

9-14

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.735.9

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Online since:

December 2012

Authors:

Koji Morita, Byung Nam Kim, Hidehiro Yoshida, Yoshio Sakka, Keijiro Hiraga

Keywords:

Accommodation Process, Flow Mechanisms, Grain Boundary Sliding (GBS), High-Strain-Rate Superplasticity (HSRS), Zro₂

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