Constitutive Equation for Superplastic Flow in Light Metallic Materials

Hiroyuki Watanabe; Toshiji Mukai; Kenji Higashi

doi:10.4028/www.scientific.net/MSF.447-448.91

Paper Titles

Cavitation Behaviors in a Tetragonal Zirconia Polycrystal Subjected to Superplastic Deformations Measured by SANS Method
p.67

Simulation of Superplastic Deformation Based on a Mantle Model
p.73

Dynamic Grain Growth in a Non-Superplastic Al-6Ni Alloy
p.79

Physical Theory of Superplastic Flow in Spatially Extended Crystalline Systems
p.85

Constitutive Equation for Superplastic Flow in Light Metallic Materials
p.91

Grain-Size-Dependent Cooperative Grain-Boundary Sliding in Superplastic Deformation
p.97

Multi-Scale Analysis of Failure during Superplastic Deformation
p.105

The Measurement of Friction for Superplastic Forming of Ti-6Al-4V
p.111

Finite Element Simulation for Superplastic Forming Process of Aluminium 5083
p.117

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Constitutive Equation for Superplastic Flow in Light Metallic Materials

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Materials Science Forum (Volumes 447-448)

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91-96

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https://doi.org/10.4028/www.scientific.net/MSF.447-448.91

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February 2004

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Hiroyuki Watanabe, Toshiji Mukai, Kenji Higashi

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Aluminium Alloy, Constitutive Equation, Effective Diffusion Coefficient, Intergranular Particles, Intragranular Particles, Magnesium Alloy

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