Magnesium Technology 2016
Published on 12. December 2016
XXVI, 402 pages
978-3-319-48114-2 (ISBN)
Description
The Magnesium Technology Symposium, the event on which this collection is based, is one of the largest yearly gatherings of magnesium specialists in the world. Papers represent all aspects of the field, ranging from primary production to applications to recycling. Moreover, papers explore everything from basic research findings to industrialization. Magnesium Technology 2016 covers a broad spectrum of current topics, including alloys and their properties; cast products and processing; wrought products and processing; forming, joining, and machining; corrosion and surface finishing; ecology; and structural applications. In addition, there is coverage of new and emerging applications.
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Alok Singh | Kiran Solanki | Michele V. Manuel
Magnesium Technology 2016
Book
02/2016
Wiley
€209.00
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Persons
The Minerals, Metals & Materials Society (TMS) is a member-driven international professional society dedicated to fostering the exchange of learning and ideas across the entire range of materials science and engineering, from minerals processing and primary metals production, to basic research and the advanced applications of materials. Included among its nearly 13,000 professional and student members are metallurgical and materials engineers, scientists, researchers, educators, and administrators from more than 70 countries on six continents. For more information on TMS, visit www.tms.org.
Content
1 - Cover [Seite 1]
2 - Half Title [Seite 2]
3 - Title Page [Seite 4]
4 - Copyright Page [Seite 5]
5 - Table of Contents [Seite 6]
6 - Preface [Seite 12]
7 - About the Editors [Seite 14]
8 - Session Chairs [Seite 23]
9 - Reviewer Pool [Seite 24]
10 - Magnesium Technology 2016 [Seite 26]
10.1 - Keynote Session [Seite 27]
10.1.1 - Challenges for Implementation of Magnesium into More Applications [Seite 28]
10.1.2 - Development of Magnesium Alloys for High Speed Trains in China [Seite 30]
10.1.3 - Korea's R&D Activities towards the Application of Wrought Mg Alloys [Seite 32]
10.1.4 - Fascinating LPSO-Structured Mg Alloys [Seite 34]
10.1.5 - Developments in High Magnesium-Content Bulk Metallic Glasses and Future Possibilities [Seite 36]
10.2 - Solidification and Casting [Seite 38]
10.2.1 - In Situ Synchrotron Radiation Diffraction of the Solidification of Mg-Dy(-Zr) Alloys [Seite 39]
10.2.2 - As Solidified Microstructure Investigation of Mg15Y and MgxYyGd (x+y=15 wt.%) Ternary Alloys [Seite 44]
10.2.3 - Development of the New High Shear Technology for Continuous Processing of Mg-Alloys for Ingot Casting [Seite 49]
10.2.4 - Dendrite Morphology and Growth Orientation of Magnesium Alloys: Simulation by Phase-Field and 3-D Characterization by Synchrotron X-Ray Tomography [Seite 54]
10.2.5 - Influence of Hot Isostatic Processing on the Microstructure and Tensile Behavior of HPDC AM50 [Seite 59]
10.2.6 - Microsegregation in High Pressure Die Cast AM70 [Seite 65]
10.2.7 - Predicting Solidification Properties of Magnesium by Molecular Dynamics Simulations [Seite 70]
10.3 - Keynote Session Part II and Primary Production and Recycling [Seite 74]
10.3.1 - A Perspective: Potential Growth in the Global Magnesium Industry - Where Is Our Research Leading Us? [Seite 75]
10.3.2 - Study on Mechanism of Magnesia Production by Reversion Reaction Process in Vacuum [Seite 77]
10.3.3 - Thermodynamic Description of Reactions between Mg and CaO [Seite 83]
10.3.4 - Atomic-Level Mechanisms of Magnesium Oxidation [Seite 89]
10.4 - Alloy Development, Diffusion and Joining [Seite 93]
10.4.1 - Development of Mg-Al-Sn-Si Alloys Using a CALPHAD Approach [Seite 94]
10.4.2 - Lattice Ordering and Microstructure of Ultra-High Strength Mg-Ca-Zn Alloys [Seite 98]
10.4.3 - Pre-Straining Effect on Precipitation Behaviour of AZ31B [Seite 104]
10.4.4 - The Effect of Ageing on the Compressive Deformation of Mg-Sn-Zn-Na Alloy [Seite 108]
10.4.5 - First-Principles Study of Diffusion Coefficients of Alloy Elements in Dilute Mg Alloys [Seite 112]
10.4.6 - Study of ZE10 Magnesium Alloy Welded Joints Produced with Disk Laser [Seite 117]
10.4.7 - Similar and Dissimilar Ultrasonic Spot Welding of a Rare-Earth Containing ZEK100 Magnesium Alloy [Seite 122]
10.4.8 - Effect of Filler Wires on Cracking along Edges of Magnesium Welds [Seite 127]
10.5 - Magnesium-Rare Earth Alloys [Seite 132]
10.5.1 - Hot Tearing in Magnesium-Rare Earth Alloys [Seite 133]
10.5.2 - Hot Tearing Susceptibility of Mg-5Nd-xZn Alloys [Seite 139]
10.5.3 - Solid Solution Strengthening in Mg-Gd Alloys [Seite 145]
10.5.4 - Effects of Homogenization on Microstructure and Mechanical Properties of a ZE20 Mg Alloy Processed by Indirect Extrusion [Seite 150]
10.5.5 - Age-Hardening of Dual Phase Mg-Sc Alloy at 573 K [Seite 156]
10.5.6 - The Structure of ?" and ?' in an Aged Mg-Nd Alloy [Seite 159]
10.6 - LPSO Alloys and Composites [Seite 163]
10.6.1 - Solid Solution Hardening in Mg-Gd-TM (TM=Ag, Zn and Zr) Alloys: An Integrated Density Functional Theory and Electron Work Function Study [Seite 164]
10.6.2 - Microstructure and Mechanical Properties New Magnesium-Zinc-Gadolinium Alloys [Seite 165]
10.6.3 - Effects of Alloying Elements on Microstructures and Mechanical Properties of Mg-Gd-Zn-Ca Alloys [Seite 170]
10.6.4 - Creep of a Mg-Zn-Y Alloy at Elevated Temperatures [Seite 174]
10.6.5 - An Insight into Use of Hollow Fly Ash Particles on the Properties of Magnesium [Seite 180]
10.6.6 - Role of SiC in Grain Refinement of Aluminum-Free Mg-Zn Alloys [Seite 182]
10.6.7 - Hot Deformation and Processing Map in an Mg-Zn-Mn-Y Alloy [Seite 187]
10.7 - Twinning and Plasticity [Seite 191]
10.7.1 - What is in a Strain Hardening "Plateau"? [Seite 192]
10.7.2 - Asymmetric Growth of Tensile Twins in Magnesium [Seite 198]
10.7.3 - Non-Dislocation Based Room Temperature Plastic Deformation Mechanism in Magnesium [Seite 202]
10.7.4 - Investigation of the Plastic Flow Field in Magnesium Alloy AZ31B in Three Orientations for Empirical Penetration Models [Seite 205]
10.7.5 - Deformation Behavior of Mg Single Crystals Compressed along c-Axis [Seite 211]
10.7.6 - The Use of Acoustic Emission and Neutron Diffraction to Reveal the Active Deformation Mechanisms in Polycrystalline Magnesium and Comparison to Theoretical Modeling [Seite 214]
10.7.7 - Strain Rate Dependent Deformation and Failure Process of Magnesium Foams [Seite 218]
10.7.8 - Exploration of Thin-Walled Magnesium Alloy Tube Extrusion for Improved Crash Performance [Seite 224]
10.7.9 - High Temperature Tensile Behaviors and Deformation Mechanisms of Mg-x%Al Alloys [Seite 230]
10.8 - Texture and Formability [Seite 236]
10.8.1 - In-Situ EBSD Observations of Recrystallization and Texture Evolution in Rolled Mg-2Zn-xCe (wt.%) [Seite 237]
10.8.2 - Non-Basal Texture Evolution during Annealing of Cold-Deformed Magnesium Alloy [Seite 238]
10.8.3 - On Modeling the Mechanical Behavior and Texture Evolution of Rolled AZ31 Mg for Complex Loadings Involving Strain Path Changes [Seite 243]
10.8.4 - Formability of Extruded Magnesium Alloy Sheets with Different Textures [Seite 249]
10.8.5 - Prediction of Magnesium Alloy Formability: The Role of Texture [Seite 255]
10.8.6 - Texture Evolution and Mechanical Properties of Mg-Li Alloy during Thermo-Mechanical Process [Seite 261]
10.8.7 - Effect of Dynamic Recrystallization on Microstructure Evolution and Texture Weakening during Annealing of High Speed Rolled AZ31 Magnesium Alloy Sheets [Seite 265]
10.9 - Corrosion [Seite 270]
10.9.1 - Numerical Investigation of the AE44-Mild Steel Galvanic Structural Joint [Seite 271]
10.9.2 - Fabrication of a Superhydrophobic Film with Self-Cleaning Property on Magnesium Alloy and Its Corrosion Resistance Properties [Seite 275]
10.9.3 - The Surface Films and Their Possible Roles in Mg Corrosion [Seite 280]
10.9.4 - Micro-Arc Oxide Film of Aluminum Coating Pre-Sprayed on AZ31 Magnesium Alloy [Seite 286]
10.10 - Poster Session [Seite 291]
10.10.1 - Study on Fatigue Mechanism of Mg-0.6at%Y Alloy by Cyclic Tensile Test [Seite 292]
10.10.2 - Mechanical Response of a Gravity Cast Mg-9Al-1Zn-0.2Sc Alloy at Strain Rates from 10-4 to 103/s [Seite 297]
11 - Magnesium-based Biodegradable Implants [Seite 302]
11.1 - Materials and Processing / Surface Modification and Corrosion [Seite 303]
11.1.1 - Fabrication, Testing and Performance of Rare Earth-Containing Magnesium Biodegradable Metals [Seite 304]
11.1.2 - Manufacturing of Osteosynthesis Systems Made of Magnesium Alloy AZ91 [Seite 306]
11.1.3 - Absorbable Filament Technologies: Wire-Drawing to Enable Next-Generation Medical Devices [Seite 312]
11.1.4 - Plasma Surface Modification of Magnesium-Based and Related Materials [Seite 317]
11.1.5 - Degradation of MgF2-Coated and Uncoated MgNd2 Specimens in Contact with Nasal Mucosa [Seite 319]
11.1.6 - Flow Induced Biodegradation Behavior of Magnesium Metal: From Bioreactors to In Vivo Models [Seite 324]
11.2 - Corrosion / Market and Clinic [Seite 327]
11.2.1 - Understanding Corrosion-Assisted Cracking of Magnesium Alloys for Bioimplant Applications [Seite 328]
11.2.2 - In Vitro Corrosion and Cytocompatibility Properties of Mg-2Gd-X(Ag, Ca) Alloys [Seite 332]
11.2.3 - Appropriate Corrosion-Fatigue Testing of Magnesium Alloys for Temporary Bioimplant Applications [Seite 337]
11.2.4 - Standardized Guidance for the Preclinical Evaluation of Absorbable Metal Implants [Seite 341]
11.2.5 - The Industrial Challenges of Manufacturing Bioabsorbable Magnesium [Seite 344]
12 - Strip Casting of Light Metals [Seite 348]
12.1 - Strip Casting Process [Seite 349]
12.1.1 - Microstructure Investigations of Inverse Segregations in Twin-Roll Cast AZ31 Strips [Seite 350]
12.2 - Strip Casting: Properties [Seite 356]
12.2.1 - Substitution of Rare Earth Elements in Magnesium Alloys for the Sheet Production via Twin Roll Casting [Seite 357]
12.2.2 - Microstructure and Mechanical Properties of Ca Containing AZX310 Alloy Sheets Produced via Twin Roll Casting Technology [Seite 363]
12.3 - Poster Session [Seite 368]
12.3.1 - Microstructure and Properties of SiCp/Al Matrix Composite Strip Fabricating by Twin-Roll Casting Process [Seite 369]
13 - Author Index [Seite 375]
14 - Subject Index [Seite 378]
2 - Half Title [Seite 2]
3 - Title Page [Seite 4]
4 - Copyright Page [Seite 5]
5 - Table of Contents [Seite 6]
6 - Preface [Seite 12]
7 - About the Editors [Seite 14]
8 - Session Chairs [Seite 23]
9 - Reviewer Pool [Seite 24]
10 - Magnesium Technology 2016 [Seite 26]
10.1 - Keynote Session [Seite 27]
10.1.1 - Challenges for Implementation of Magnesium into More Applications [Seite 28]
10.1.2 - Development of Magnesium Alloys for High Speed Trains in China [Seite 30]
10.1.3 - Korea's R&D Activities towards the Application of Wrought Mg Alloys [Seite 32]
10.1.4 - Fascinating LPSO-Structured Mg Alloys [Seite 34]
10.1.5 - Developments in High Magnesium-Content Bulk Metallic Glasses and Future Possibilities [Seite 36]
10.2 - Solidification and Casting [Seite 38]
10.2.1 - In Situ Synchrotron Radiation Diffraction of the Solidification of Mg-Dy(-Zr) Alloys [Seite 39]
10.2.2 - As Solidified Microstructure Investigation of Mg15Y and MgxYyGd (x+y=15 wt.%) Ternary Alloys [Seite 44]
10.2.3 - Development of the New High Shear Technology for Continuous Processing of Mg-Alloys for Ingot Casting [Seite 49]
10.2.4 - Dendrite Morphology and Growth Orientation of Magnesium Alloys: Simulation by Phase-Field and 3-D Characterization by Synchrotron X-Ray Tomography [Seite 54]
10.2.5 - Influence of Hot Isostatic Processing on the Microstructure and Tensile Behavior of HPDC AM50 [Seite 59]
10.2.6 - Microsegregation in High Pressure Die Cast AM70 [Seite 65]
10.2.7 - Predicting Solidification Properties of Magnesium by Molecular Dynamics Simulations [Seite 70]
10.3 - Keynote Session Part II and Primary Production and Recycling [Seite 74]
10.3.1 - A Perspective: Potential Growth in the Global Magnesium Industry - Where Is Our Research Leading Us? [Seite 75]
10.3.2 - Study on Mechanism of Magnesia Production by Reversion Reaction Process in Vacuum [Seite 77]
10.3.3 - Thermodynamic Description of Reactions between Mg and CaO [Seite 83]
10.3.4 - Atomic-Level Mechanisms of Magnesium Oxidation [Seite 89]
10.4 - Alloy Development, Diffusion and Joining [Seite 93]
10.4.1 - Development of Mg-Al-Sn-Si Alloys Using a CALPHAD Approach [Seite 94]
10.4.2 - Lattice Ordering and Microstructure of Ultra-High Strength Mg-Ca-Zn Alloys [Seite 98]
10.4.3 - Pre-Straining Effect on Precipitation Behaviour of AZ31B [Seite 104]
10.4.4 - The Effect of Ageing on the Compressive Deformation of Mg-Sn-Zn-Na Alloy [Seite 108]
10.4.5 - First-Principles Study of Diffusion Coefficients of Alloy Elements in Dilute Mg Alloys [Seite 112]
10.4.6 - Study of ZE10 Magnesium Alloy Welded Joints Produced with Disk Laser [Seite 117]
10.4.7 - Similar and Dissimilar Ultrasonic Spot Welding of a Rare-Earth Containing ZEK100 Magnesium Alloy [Seite 122]
10.4.8 - Effect of Filler Wires on Cracking along Edges of Magnesium Welds [Seite 127]
10.5 - Magnesium-Rare Earth Alloys [Seite 132]
10.5.1 - Hot Tearing in Magnesium-Rare Earth Alloys [Seite 133]
10.5.2 - Hot Tearing Susceptibility of Mg-5Nd-xZn Alloys [Seite 139]
10.5.3 - Solid Solution Strengthening in Mg-Gd Alloys [Seite 145]
10.5.4 - Effects of Homogenization on Microstructure and Mechanical Properties of a ZE20 Mg Alloy Processed by Indirect Extrusion [Seite 150]
10.5.5 - Age-Hardening of Dual Phase Mg-Sc Alloy at 573 K [Seite 156]
10.5.6 - The Structure of ?" and ?' in an Aged Mg-Nd Alloy [Seite 159]
10.6 - LPSO Alloys and Composites [Seite 163]
10.6.1 - Solid Solution Hardening in Mg-Gd-TM (TM=Ag, Zn and Zr) Alloys: An Integrated Density Functional Theory and Electron Work Function Study [Seite 164]
10.6.2 - Microstructure and Mechanical Properties New Magnesium-Zinc-Gadolinium Alloys [Seite 165]
10.6.3 - Effects of Alloying Elements on Microstructures and Mechanical Properties of Mg-Gd-Zn-Ca Alloys [Seite 170]
10.6.4 - Creep of a Mg-Zn-Y Alloy at Elevated Temperatures [Seite 174]
10.6.5 - An Insight into Use of Hollow Fly Ash Particles on the Properties of Magnesium [Seite 180]
10.6.6 - Role of SiC in Grain Refinement of Aluminum-Free Mg-Zn Alloys [Seite 182]
10.6.7 - Hot Deformation and Processing Map in an Mg-Zn-Mn-Y Alloy [Seite 187]
10.7 - Twinning and Plasticity [Seite 191]
10.7.1 - What is in a Strain Hardening "Plateau"? [Seite 192]
10.7.2 - Asymmetric Growth of Tensile Twins in Magnesium [Seite 198]
10.7.3 - Non-Dislocation Based Room Temperature Plastic Deformation Mechanism in Magnesium [Seite 202]
10.7.4 - Investigation of the Plastic Flow Field in Magnesium Alloy AZ31B in Three Orientations for Empirical Penetration Models [Seite 205]
10.7.5 - Deformation Behavior of Mg Single Crystals Compressed along c-Axis [Seite 211]
10.7.6 - The Use of Acoustic Emission and Neutron Diffraction to Reveal the Active Deformation Mechanisms in Polycrystalline Magnesium and Comparison to Theoretical Modeling [Seite 214]
10.7.7 - Strain Rate Dependent Deformation and Failure Process of Magnesium Foams [Seite 218]
10.7.8 - Exploration of Thin-Walled Magnesium Alloy Tube Extrusion for Improved Crash Performance [Seite 224]
10.7.9 - High Temperature Tensile Behaviors and Deformation Mechanisms of Mg-x%Al Alloys [Seite 230]
10.8 - Texture and Formability [Seite 236]
10.8.1 - In-Situ EBSD Observations of Recrystallization and Texture Evolution in Rolled Mg-2Zn-xCe (wt.%) [Seite 237]
10.8.2 - Non-Basal Texture Evolution during Annealing of Cold-Deformed Magnesium Alloy [Seite 238]
10.8.3 - On Modeling the Mechanical Behavior and Texture Evolution of Rolled AZ31 Mg for Complex Loadings Involving Strain Path Changes [Seite 243]
10.8.4 - Formability of Extruded Magnesium Alloy Sheets with Different Textures [Seite 249]
10.8.5 - Prediction of Magnesium Alloy Formability: The Role of Texture [Seite 255]
10.8.6 - Texture Evolution and Mechanical Properties of Mg-Li Alloy during Thermo-Mechanical Process [Seite 261]
10.8.7 - Effect of Dynamic Recrystallization on Microstructure Evolution and Texture Weakening during Annealing of High Speed Rolled AZ31 Magnesium Alloy Sheets [Seite 265]
10.9 - Corrosion [Seite 270]
10.9.1 - Numerical Investigation of the AE44-Mild Steel Galvanic Structural Joint [Seite 271]
10.9.2 - Fabrication of a Superhydrophobic Film with Self-Cleaning Property on Magnesium Alloy and Its Corrosion Resistance Properties [Seite 275]
10.9.3 - The Surface Films and Their Possible Roles in Mg Corrosion [Seite 280]
10.9.4 - Micro-Arc Oxide Film of Aluminum Coating Pre-Sprayed on AZ31 Magnesium Alloy [Seite 286]
10.10 - Poster Session [Seite 291]
10.10.1 - Study on Fatigue Mechanism of Mg-0.6at%Y Alloy by Cyclic Tensile Test [Seite 292]
10.10.2 - Mechanical Response of a Gravity Cast Mg-9Al-1Zn-0.2Sc Alloy at Strain Rates from 10-4 to 103/s [Seite 297]
11 - Magnesium-based Biodegradable Implants [Seite 302]
11.1 - Materials and Processing / Surface Modification and Corrosion [Seite 303]
11.1.1 - Fabrication, Testing and Performance of Rare Earth-Containing Magnesium Biodegradable Metals [Seite 304]
11.1.2 - Manufacturing of Osteosynthesis Systems Made of Magnesium Alloy AZ91 [Seite 306]
11.1.3 - Absorbable Filament Technologies: Wire-Drawing to Enable Next-Generation Medical Devices [Seite 312]
11.1.4 - Plasma Surface Modification of Magnesium-Based and Related Materials [Seite 317]
11.1.5 - Degradation of MgF2-Coated and Uncoated MgNd2 Specimens in Contact with Nasal Mucosa [Seite 319]
11.1.6 - Flow Induced Biodegradation Behavior of Magnesium Metal: From Bioreactors to In Vivo Models [Seite 324]
11.2 - Corrosion / Market and Clinic [Seite 327]
11.2.1 - Understanding Corrosion-Assisted Cracking of Magnesium Alloys for Bioimplant Applications [Seite 328]
11.2.2 - In Vitro Corrosion and Cytocompatibility Properties of Mg-2Gd-X(Ag, Ca) Alloys [Seite 332]
11.2.3 - Appropriate Corrosion-Fatigue Testing of Magnesium Alloys for Temporary Bioimplant Applications [Seite 337]
11.2.4 - Standardized Guidance for the Preclinical Evaluation of Absorbable Metal Implants [Seite 341]
11.2.5 - The Industrial Challenges of Manufacturing Bioabsorbable Magnesium [Seite 344]
12 - Strip Casting of Light Metals [Seite 348]
12.1 - Strip Casting Process [Seite 349]
12.1.1 - Microstructure Investigations of Inverse Segregations in Twin-Roll Cast AZ31 Strips [Seite 350]
12.2 - Strip Casting: Properties [Seite 356]
12.2.1 - Substitution of Rare Earth Elements in Magnesium Alloys for the Sheet Production via Twin Roll Casting [Seite 357]
12.2.2 - Microstructure and Mechanical Properties of Ca Containing AZX310 Alloy Sheets Produced via Twin Roll Casting Technology [Seite 363]
12.3 - Poster Session [Seite 368]
12.3.1 - Microstructure and Properties of SiCp/Al Matrix Composite Strip Fabricating by Twin-Roll Casting Process [Seite 369]
13 - Author Index [Seite 375]
14 - Subject Index [Seite 378]
