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| Preface | |
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| Development of Advanced Superplastic Forming Processes | |
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| The History and Current State-of-the-Art in Airframe ManufacturingUsing Superplastic Forming Technologies | |
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| General Motors' Quick Plastic Forming Process | |
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| Heating Aluminum Sheet to Enable High-Strain Forming | |
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| High Temperature Properties of Tooling Materials Utilized for SuperplasticForming Processes | |
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| Mass Production of a Spare Tire Housing for an Automobile | |
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| Evaluation of Die Coatings for Superplastic Forming Processes | |
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| Double Action QPF Tool | |
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| SSR Fenders Produced by Math-Based QPF Technology | |
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| Advances in Superplastic Al-Mg Materials | |
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| An Overview of Creep Deformation Behaviors in 5000-Series and Al-MgAlloys | |
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| Texture Development and Dynamic Recrystallization in AA5083 DuringSuperplastic Forming at Various Strain Rates | |
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| Bulge Testing of Superplastic AA5083 Aluminum Sheet | |
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| Deformation Mechanisms and Cavity Formation in Superplastic AA5083 | |
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| Superplastic Failure Mechanisms and Ductility of AA5083 | |
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| Microstructural Characterization of Superplastic Forming (SPF) AA5083Aluminum Sheet | |
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| Post-Form Properties of Superplastically Formed AA5083 Aluminum Sheet | |
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| Rolling Process Optimization for Superplastic 5083 Al Sheet | |
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| Advances in Superplastic Light Alloys | |
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| Research Opportunities for Automotive Superplastic Forming Alloys | |
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| Superplasticity in a Hot-Extruded 15% vol. Al2O3 Particulate-Reinforced6061 Al Composite | |
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| Achieving Superplasticity in Light Alloys through the Application of SeverePlastic Deformation | |
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| High-Strain-Rate Superplasticity in Aluminum Alloys Via Friction StirProcessing | |
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| Advanced Superplastic Materials and the Science of Superplasticity | |
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| Cooperative Grain Boundary Processes in Superplastic Forming UnderDifferent Deformation States | |
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| Influence of Grain Boundary Structure and Composition on SuperplasticDeformation | |
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| Superplasticity in Zr-Based Bulk Metallic Glasses: A Critical Overview | |
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| Transformation Superplasticity of Titanium by Reversible Hydrogen Cycling | |
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| Research and Development Towards Grain-Boundary-Plasticity fromSuperplasticity | |
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| Deformation of Superplastic Al2O3/Y-TZP Particulate and ParticulateLaminate Composites | |
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| Texture and Microstructure of Superplastic 7475 Aluminum | |
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| Studies of Void Growth and Interaction in a Eutectic Sn-Pb Alloy | |
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| Modeling of Superplastic Forming Processes and Materials | |
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| Influence of Friction and Die Geometry on Simulation of SuperplasticForming of Al-Mg Alloys | |
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| Development of MARC for Analysis of Quick Plastic Forming Processes | |
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| Effect of the Constitutive Equation on MARC Analysis of Quick PlasticForming | |
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| Mechanical Behavior and Modeling of AA5083 at 450�C | |
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| Forming Limit Diagram of a Superplastic Formable AA5083 AluminiumAlloy | |
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| Integrated Approach to Optimization of Superplastic Forming | |
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| Aspects of Element Formulation and Strain Rate Control in the NumericalModeling of Superplastic Forming | |
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| Author Index | |
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| Subject Index | |