Magnesium Technology 2015
1st Edition
Published on 26. December 2016
XX, 497 pages
978-3-319-48185-2 (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 2015 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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Michele V. Manuel | Alok Singh | Martyn Alderman
Magnesium Technology 2015
Book
04/2015
Wiley
€164.65
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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 17]
9 - Reviewer Pool [Seite 18]
10 - Keynote Session [Seite 20]
10.1 - Reducing Weight for Transportation Applications: Technology Challenges and Opportunities [Seite 21]
10.2 - The Application of Magnesium Alloys in Aircraft Interiors - Changing the Rules [Seite 22]
10.3 - Emerging Science and Research Opportunities for Metals and Metallic Nanostructures: A Report on the NSF MMNWorkshop [Seite 23]
10.4 - Solute Segregation and Aggregation in Mg Alloys [Seite 24]
11 - Elevated Temperature and Creep [Seite 25]
11.1 - Three Decades of Electron Backscatter Diffraction of Magnesium: What Has It Taught Us? [Seite 26]
11.2 - Measuring and Modeling the Effects of Mechanical Twinning on the Behavior of Magnesium Alloys [Seite 27]
11.3 - Microstructure and Properties of Aged vs Crept Mg-Al-Zn-Sn Alloys with Additions of Nd and Ce [Seite 30]
11.4 - Hot Compression Behavior of Magnesium Alloys ZE20 and AM30 [Seite 36]
11.5 - Creep Deformation Mechanisms and Related Microstucture Development of AZ31 Magnesium Alloy [Seite 40]
11.6 - Creep Response of a Zn Containing Mg-Nd-La Alloy [Seite 46]
12 - Primary, Sustainability, Recycling and Processing [Seite 51]
12.1 - Thermal Electrolytic Production of Mg from MgO: Reflections on Commercial Viability [Seite 52]
12.2 - Study on Compressive Strength of Pellets for the Novel Silicothermic Process [Seite 58]
12.3 - Carbothermal Production of Magnesium in Vacuum [Seite 63]
12.4 - Effect of Argon Flow Rate on the Condensation of Magnesium Vapor from Carbothermic Reduction of Magnesia [Seite 68]
12.5 - Environmental Impact of Magnesium Production by Carbothermic Reduction in Vacuum [Seite 73]
12.6 - Comparative Environmental Benefits of Lightweight Design in the Automotive Sector: The Case Study of RecycledMagnesium against CFRP and Steel [Seite 78]
12.7 - In Situ Synchrotron Radiation Diffraction during Solidification of Mg15Gd: Effect of Cooling Rate [Seite 84]
12.8 - Microstructures and Tensile Properties of Mg-4Al-4La-0.4Mn-XB (X = 0, 0.01, 0.02, 0.03) Alloy [Seite 90]
12.9 - The Role of Bismuth in Grain Refinement of Magnesium and Its Alloys [Seite 96]
13 - Deformation I [Seite 100]
13.1 - In Situ Neutron Diffraction Study of the Deformation Mechanisms in Solutionized Mg-Zn Alloys [Seite 101]
13.2 - Investigation of Compression Behavior of Mg-4Zn-2(Nd,Gd)-0.5Zr at 350°C by In Situ SynchrotronRadiation Diffraction [Seite 107]
13.3 - The Deformation Behavior, Microstructure and Mechanical Properties of Cast and Extruded Mg-1Mn-xNd (wt%) atTemperatures between 50°C and 250°C [Seite 112]
13.4 - Effect of Dynamic Strain Aging on the Strain Rate Sensitivity of a Mg-2Zn-2Nd Alloy [Seite 118]
13.5 - The Deformation Gradient of Interfacial Defects on Twin-Like Interfaces [Seite 123]
13.6 - Geometrically Necessary Twins in Bending of an AZ31 Sheet [Seite 128]
13.7 - Deformation Twinning Effects on Texture and Microstructure of AZ31B Magnesium Rolled Samples [Seite 134]
13.8 - Dislocation-Twin Interactions in Magnesium Alloy AZ31 [Seite 139]
13.9 - Role of Tensile Twinning on Fracture Behavior of Magnesium AZ31 Alloy [Seite 145]
14 - Deformation II [Seite 151]
14.1 - New Model Predicting the Unusual Buckling Behavior of AZ31 Mg [Seite 152]
14.2 - Why Do Magnesium Alloys Develop Sharp Textures upon Dynamic Recrystallization? [Seite 157]
14.3 - Crystal Plasticity Modeling of the Dynamic Behavior of Magnesium Alloy, WE43-T5, Plate [Seite 162]
14.4 - Micromechanical Modeling of Evolving Anisotropy in AZ31 Mg for Various Strain Paths [Seite 168]
14.5 - Recrystallization Behavior of the Magnesium Alloy ZE20 [Seite 173]
14.6 - Ballistic Characterization of the Scalability of Mg Alloy AMX602 [Seite 179]
14.7 - Deformation Response of Mg-Y Alloys under Dynamic Loading [Seite 184]
14.8 - Large Strain Behaviour of ZEK100 Magnesium Alloy at Various Strain Rates [Seite 185]
14.9 - Effect of Solute Segregation on Fracture Behavior of Mg Alloy [Seite 190]
15 - Wrought [Seite 194]
15.1 - Development of Thin-Walled Magnesium Alloy Extrusions for Improved Crash PerformanceBased upon Texture Control [Seite 195]
15.2 - Role of Zr in the Microstructure Evolution in Mg-Zn-Zr Based Wrought Alloys [Seite 201]
15.3 - Effect of Alloy Composition on Microstructure and Strength of Fine Grained Extruded Mg-Zn-YAlloys Containing Quasicrystal Phase [Seite 206]
15.4 - An Extruded and Peak Aged Mg-5Gd-3Y-1Zn-Zr Alloy with High Strength [Seite 212]
15.5 - Strengthening in Thermomechanically Processed Magnesium Alloys [Seite 216]
15.6 - Microstructures and Mechanical Properties of Mg-1at%X Alloys Processed with High-Pressure Torsion [Seite 222]
15.7 - Dependence of Compression-Tension Loading on Twinning in Wrought Mg Alloy [Seite 228]
15.8 - Effect of Mn Content on Microstructures and Mechanical Properties of Mg-Al-Ca-Mn AlloysFabricated by High-Speed Extrusion [Seite 232]
15.9 - Effects of Extrusion Processing and Heat Treatment on Mechanical Property and Heat Dissipation Performance ofMg-2.5Nd-1.0Zn-0.5Zr Alloy [Seite 238]
16 - Forming and Alloy Design [Seite 242]
16.1 - Effect of Initial Microstructures on Cold-Rollability of RE-Free Magnesium Alloys [Seite 243]
16.2 - Studies on the Magnesium Alloys Cladding in the Plastic Forming Processes (Die Forging and Extrusion)Using as the Clad Layer Corrosion Resistant Aluminum Alloys [Seite 247]
16.3 - The Effects of Plastic Anisotropy in Warm and Hot Forming of Magnesium Sheet Materials [Seite 253]
16.4 - Effect of Heat Treatment on Microstructure and Damping Capacity of Twin Roll Cast ZK60 Strip [Seite 257]
16.5 - Deformation Behavior of Rolled Magnesium Slabs and Twin Roll Cast Strips Studied by the AcousticEmission Technique [Seite 262]
16.6 - Effects of Texture and Alloying Elements on Stretch Formability of Mg Alloy Sheets [Seite 266]
16.7 - Progress in Thermodynamic Database Development for ICME of Mg Alloys [Seite 271]
16.8 - Simulation of Concurrent Precipitation of Two Strengthening Phases in Magnesium Alloys [Seite 276]
16.9 - Strengthening Mechanisms in Mg97Zn1Y2 Alloys [Seite 281]
17 - Corrosion, Coatings, Fatigue, and Fracture [Seite 286]
17.1 - Fatigue and Corrosion Fatigue of Cold Drawn WE43 Wires [Seite 287]
17.2 - Deformation and Failure Modes of Rapidly Solidified, Ultra-Fine Grain, AMX602 and ZAXE1711Magnesium Alloys [Seite 292]
17.3 - Effect of Sn:Zn Ratio on Corrosion Behavior of Mg-aSn-bZn Extrusions [Seite 298]
17.4 - Stress Corrosion Cracking of ZEK100 Magnesium Alloy for Automotive Applications [Seite 302]
17.5 - Effect of Ca and Y on Corrosion Behavior of Extruded AZ Series Mg Alloys [Seite 306]
17.6 - Characterization of Coatings on Steel Self-Piercing Rivets for Use with Magnesium Alloys [Seite 310]
17.7 - Investigation of Coating and Corrosion Mitigation Strategies in Magnesium/Mixed Metal Assemblies [Seite 316]
17.8 - Influence of Pulse Time on the Structural and Tribological Properties of Micro Arc Oxidized AZ91DMagnesium Alloy [Seite 322]
17.9 - Electroless Ni-P/Nano-SiO2 Composite Plating on Dual Phase Magnesium-Lithium Alloy [Seite 326]
18 - Casting and Metal Matrix Composites [Seite 331]
18.1 - Process-Structure-Property Correlations for HPDC AM60B [Seite 332]
18.2 - Influence of Alloy Composition on Cast Cracking and Heat Resistance of Mg-Al-Ca Cast Alloy [Seite 338]
18.3 - Microstructural Scale Effects on Thermal Expansion Behaviour of Cast AZ91D [Seite 342]
18.4 - Precipitation Sequence in a Mg-Sm-Zn-Zr Alloy [Seite 347]
18.5 - The Exomet Project: EU/ESA Research on High-Performance Light-Metal Alloys and Nanocomposites [Seite 353]
18.6 - Phase Evaluation of Sr and CaO Added Mg-Al-Si Alloys [Seite 356]
18.7 - High Performance Mg6Zn Nanocomposites Fabricated through Friction Stir Processing [Seite 361]
18.8 - Synthesis and Characterization of Novel Magnesium Materials Containing Copper-Titanium Based (Cu50Ti50) Amorphous Alloy Particles [Seite 365]
19 - Biomedical Applications [Seite 369]
19.1 - Mechanical and Corrosive Properties of Two Magnesium Wires: Mg4Gd and Mg6Ag [Seite 370]
19.2 - Degradation Behavior of Mg-Ca Nail after Penetration into Artificial Bone [Seite 376]
19.3 - Improving the Corrosion Resistance of Biodegradable Magnesium Alloys by Diffusion Coating Process [Seite 380]
19.4 - Effects of Heat Treatment on Bio-Corrosion Properties of Mg-Zn-xMn (x= 0.5, 1.0, and 1.5 wt.%)Alloys as Biodegradable Materials [Seite 384]
19.5 - Effects of Ti and TiB2 Nanoparticulates on Room Temperature Mechanical Properties and In Vitro Degradation of Pure Mg [Seite 389]
19.6 - Microstructure and Properties of Magnesium Alloy Mg-1Zn-1Ca (ZX11) [Seite 395]
19.7 - Powder Metallurgical Synthesis of Biodegradable Mg-Hydroxyapatite Compositesfor Biomedical Applications [Seite 400]
19.8 - Correlation between Mechanical Behaviour and Microstructure in the Mg-Ca-Si-Sr Systemfor Degradable Biomaterials Based on Thermodynamic Calculations [Seite 405]
19.9 - Investigation of Al Coated Mg for Biomedical Applications [Seite 411]
20 - Functional and Emerging Alloys [Seite 416]
20.1 - Microstructure and Mechanical Properties of a Magnesium-Aluminium-Erbium Alloy [Seite 417]
20.2 - Microstructure and Properties of Cobalt-and Zinc-Containing Magnetic Magnesium AlloysProcessed by High-Pressure Die Casting [Seite 422]
20.3 - Effects of La Addition on Thermal Conductivity and Mechanical Properties of Mg-4Zn-0.5CaO Alloys [Seite 426]
21 - Strip Casting of Light Metals [Seite 430]
21.1 - Modeling and Properties [Seite 430]
21.1.1 - Twin Roll Casting of Magnesium Strip at Canmet Materials - Modeling and Experiments [Seite 431]
21.1.2 - Microstructure Evolution of Different Magnesium Alloys during Twin Roll Casting [Seite 435]
21.1.3 - The Microstructure and Texture Development during Twin Roll Casting and Rolling ofMagnesium Alloy AZ31 [Seite 441]
21.2 - Process Technology [Seite 447]
21.2.1 - Magnesium Twin-Roll Casting Benefits from Aluminium Heritage [Seite 448]
21.2.2 - Innovations in the Process Technology for Manufacturing Magnesium Alloy Sheet [Seite 454]
22 - Author Index [Seite 460]
23 - Subject Index [Seite 463]
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 17]
9 - Reviewer Pool [Seite 18]
10 - Keynote Session [Seite 20]
10.1 - Reducing Weight for Transportation Applications: Technology Challenges and Opportunities [Seite 21]
10.2 - The Application of Magnesium Alloys in Aircraft Interiors - Changing the Rules [Seite 22]
10.3 - Emerging Science and Research Opportunities for Metals and Metallic Nanostructures: A Report on the NSF MMNWorkshop [Seite 23]
10.4 - Solute Segregation and Aggregation in Mg Alloys [Seite 24]
11 - Elevated Temperature and Creep [Seite 25]
11.1 - Three Decades of Electron Backscatter Diffraction of Magnesium: What Has It Taught Us? [Seite 26]
11.2 - Measuring and Modeling the Effects of Mechanical Twinning on the Behavior of Magnesium Alloys [Seite 27]
11.3 - Microstructure and Properties of Aged vs Crept Mg-Al-Zn-Sn Alloys with Additions of Nd and Ce [Seite 30]
11.4 - Hot Compression Behavior of Magnesium Alloys ZE20 and AM30 [Seite 36]
11.5 - Creep Deformation Mechanisms and Related Microstucture Development of AZ31 Magnesium Alloy [Seite 40]
11.6 - Creep Response of a Zn Containing Mg-Nd-La Alloy [Seite 46]
12 - Primary, Sustainability, Recycling and Processing [Seite 51]
12.1 - Thermal Electrolytic Production of Mg from MgO: Reflections on Commercial Viability [Seite 52]
12.2 - Study on Compressive Strength of Pellets for the Novel Silicothermic Process [Seite 58]
12.3 - Carbothermal Production of Magnesium in Vacuum [Seite 63]
12.4 - Effect of Argon Flow Rate on the Condensation of Magnesium Vapor from Carbothermic Reduction of Magnesia [Seite 68]
12.5 - Environmental Impact of Magnesium Production by Carbothermic Reduction in Vacuum [Seite 73]
12.6 - Comparative Environmental Benefits of Lightweight Design in the Automotive Sector: The Case Study of RecycledMagnesium against CFRP and Steel [Seite 78]
12.7 - In Situ Synchrotron Radiation Diffraction during Solidification of Mg15Gd: Effect of Cooling Rate [Seite 84]
12.8 - Microstructures and Tensile Properties of Mg-4Al-4La-0.4Mn-XB (X = 0, 0.01, 0.02, 0.03) Alloy [Seite 90]
12.9 - The Role of Bismuth in Grain Refinement of Magnesium and Its Alloys [Seite 96]
13 - Deformation I [Seite 100]
13.1 - In Situ Neutron Diffraction Study of the Deformation Mechanisms in Solutionized Mg-Zn Alloys [Seite 101]
13.2 - Investigation of Compression Behavior of Mg-4Zn-2(Nd,Gd)-0.5Zr at 350°C by In Situ SynchrotronRadiation Diffraction [Seite 107]
13.3 - The Deformation Behavior, Microstructure and Mechanical Properties of Cast and Extruded Mg-1Mn-xNd (wt%) atTemperatures between 50°C and 250°C [Seite 112]
13.4 - Effect of Dynamic Strain Aging on the Strain Rate Sensitivity of a Mg-2Zn-2Nd Alloy [Seite 118]
13.5 - The Deformation Gradient of Interfacial Defects on Twin-Like Interfaces [Seite 123]
13.6 - Geometrically Necessary Twins in Bending of an AZ31 Sheet [Seite 128]
13.7 - Deformation Twinning Effects on Texture and Microstructure of AZ31B Magnesium Rolled Samples [Seite 134]
13.8 - Dislocation-Twin Interactions in Magnesium Alloy AZ31 [Seite 139]
13.9 - Role of Tensile Twinning on Fracture Behavior of Magnesium AZ31 Alloy [Seite 145]
14 - Deformation II [Seite 151]
14.1 - New Model Predicting the Unusual Buckling Behavior of AZ31 Mg [Seite 152]
14.2 - Why Do Magnesium Alloys Develop Sharp Textures upon Dynamic Recrystallization? [Seite 157]
14.3 - Crystal Plasticity Modeling of the Dynamic Behavior of Magnesium Alloy, WE43-T5, Plate [Seite 162]
14.4 - Micromechanical Modeling of Evolving Anisotropy in AZ31 Mg for Various Strain Paths [Seite 168]
14.5 - Recrystallization Behavior of the Magnesium Alloy ZE20 [Seite 173]
14.6 - Ballistic Characterization of the Scalability of Mg Alloy AMX602 [Seite 179]
14.7 - Deformation Response of Mg-Y Alloys under Dynamic Loading [Seite 184]
14.8 - Large Strain Behaviour of ZEK100 Magnesium Alloy at Various Strain Rates [Seite 185]
14.9 - Effect of Solute Segregation on Fracture Behavior of Mg Alloy [Seite 190]
15 - Wrought [Seite 194]
15.1 - Development of Thin-Walled Magnesium Alloy Extrusions for Improved Crash PerformanceBased upon Texture Control [Seite 195]
15.2 - Role of Zr in the Microstructure Evolution in Mg-Zn-Zr Based Wrought Alloys [Seite 201]
15.3 - Effect of Alloy Composition on Microstructure and Strength of Fine Grained Extruded Mg-Zn-YAlloys Containing Quasicrystal Phase [Seite 206]
15.4 - An Extruded and Peak Aged Mg-5Gd-3Y-1Zn-Zr Alloy with High Strength [Seite 212]
15.5 - Strengthening in Thermomechanically Processed Magnesium Alloys [Seite 216]
15.6 - Microstructures and Mechanical Properties of Mg-1at%X Alloys Processed with High-Pressure Torsion [Seite 222]
15.7 - Dependence of Compression-Tension Loading on Twinning in Wrought Mg Alloy [Seite 228]
15.8 - Effect of Mn Content on Microstructures and Mechanical Properties of Mg-Al-Ca-Mn AlloysFabricated by High-Speed Extrusion [Seite 232]
15.9 - Effects of Extrusion Processing and Heat Treatment on Mechanical Property and Heat Dissipation Performance ofMg-2.5Nd-1.0Zn-0.5Zr Alloy [Seite 238]
16 - Forming and Alloy Design [Seite 242]
16.1 - Effect of Initial Microstructures on Cold-Rollability of RE-Free Magnesium Alloys [Seite 243]
16.2 - Studies on the Magnesium Alloys Cladding in the Plastic Forming Processes (Die Forging and Extrusion)Using as the Clad Layer Corrosion Resistant Aluminum Alloys [Seite 247]
16.3 - The Effects of Plastic Anisotropy in Warm and Hot Forming of Magnesium Sheet Materials [Seite 253]
16.4 - Effect of Heat Treatment on Microstructure and Damping Capacity of Twin Roll Cast ZK60 Strip [Seite 257]
16.5 - Deformation Behavior of Rolled Magnesium Slabs and Twin Roll Cast Strips Studied by the AcousticEmission Technique [Seite 262]
16.6 - Effects of Texture and Alloying Elements on Stretch Formability of Mg Alloy Sheets [Seite 266]
16.7 - Progress in Thermodynamic Database Development for ICME of Mg Alloys [Seite 271]
16.8 - Simulation of Concurrent Precipitation of Two Strengthening Phases in Magnesium Alloys [Seite 276]
16.9 - Strengthening Mechanisms in Mg97Zn1Y2 Alloys [Seite 281]
17 - Corrosion, Coatings, Fatigue, and Fracture [Seite 286]
17.1 - Fatigue and Corrosion Fatigue of Cold Drawn WE43 Wires [Seite 287]
17.2 - Deformation and Failure Modes of Rapidly Solidified, Ultra-Fine Grain, AMX602 and ZAXE1711Magnesium Alloys [Seite 292]
17.3 - Effect of Sn:Zn Ratio on Corrosion Behavior of Mg-aSn-bZn Extrusions [Seite 298]
17.4 - Stress Corrosion Cracking of ZEK100 Magnesium Alloy for Automotive Applications [Seite 302]
17.5 - Effect of Ca and Y on Corrosion Behavior of Extruded AZ Series Mg Alloys [Seite 306]
17.6 - Characterization of Coatings on Steel Self-Piercing Rivets for Use with Magnesium Alloys [Seite 310]
17.7 - Investigation of Coating and Corrosion Mitigation Strategies in Magnesium/Mixed Metal Assemblies [Seite 316]
17.8 - Influence of Pulse Time on the Structural and Tribological Properties of Micro Arc Oxidized AZ91DMagnesium Alloy [Seite 322]
17.9 - Electroless Ni-P/Nano-SiO2 Composite Plating on Dual Phase Magnesium-Lithium Alloy [Seite 326]
18 - Casting and Metal Matrix Composites [Seite 331]
18.1 - Process-Structure-Property Correlations for HPDC AM60B [Seite 332]
18.2 - Influence of Alloy Composition on Cast Cracking and Heat Resistance of Mg-Al-Ca Cast Alloy [Seite 338]
18.3 - Microstructural Scale Effects on Thermal Expansion Behaviour of Cast AZ91D [Seite 342]
18.4 - Precipitation Sequence in a Mg-Sm-Zn-Zr Alloy [Seite 347]
18.5 - The Exomet Project: EU/ESA Research on High-Performance Light-Metal Alloys and Nanocomposites [Seite 353]
18.6 - Phase Evaluation of Sr and CaO Added Mg-Al-Si Alloys [Seite 356]
18.7 - High Performance Mg6Zn Nanocomposites Fabricated through Friction Stir Processing [Seite 361]
18.8 - Synthesis and Characterization of Novel Magnesium Materials Containing Copper-Titanium Based (Cu50Ti50) Amorphous Alloy Particles [Seite 365]
19 - Biomedical Applications [Seite 369]
19.1 - Mechanical and Corrosive Properties of Two Magnesium Wires: Mg4Gd and Mg6Ag [Seite 370]
19.2 - Degradation Behavior of Mg-Ca Nail after Penetration into Artificial Bone [Seite 376]
19.3 - Improving the Corrosion Resistance of Biodegradable Magnesium Alloys by Diffusion Coating Process [Seite 380]
19.4 - Effects of Heat Treatment on Bio-Corrosion Properties of Mg-Zn-xMn (x= 0.5, 1.0, and 1.5 wt.%)Alloys as Biodegradable Materials [Seite 384]
19.5 - Effects of Ti and TiB2 Nanoparticulates on Room Temperature Mechanical Properties and In Vitro Degradation of Pure Mg [Seite 389]
19.6 - Microstructure and Properties of Magnesium Alloy Mg-1Zn-1Ca (ZX11) [Seite 395]
19.7 - Powder Metallurgical Synthesis of Biodegradable Mg-Hydroxyapatite Compositesfor Biomedical Applications [Seite 400]
19.8 - Correlation between Mechanical Behaviour and Microstructure in the Mg-Ca-Si-Sr Systemfor Degradable Biomaterials Based on Thermodynamic Calculations [Seite 405]
19.9 - Investigation of Al Coated Mg for Biomedical Applications [Seite 411]
20 - Functional and Emerging Alloys [Seite 416]
20.1 - Microstructure and Mechanical Properties of a Magnesium-Aluminium-Erbium Alloy [Seite 417]
20.2 - Microstructure and Properties of Cobalt-and Zinc-Containing Magnetic Magnesium AlloysProcessed by High-Pressure Die Casting [Seite 422]
20.3 - Effects of La Addition on Thermal Conductivity and Mechanical Properties of Mg-4Zn-0.5CaO Alloys [Seite 426]
21 - Strip Casting of Light Metals [Seite 430]
21.1 - Modeling and Properties [Seite 430]
21.1.1 - Twin Roll Casting of Magnesium Strip at Canmet Materials - Modeling and Experiments [Seite 431]
21.1.2 - Microstructure Evolution of Different Magnesium Alloys during Twin Roll Casting [Seite 435]
21.1.3 - The Microstructure and Texture Development during Twin Roll Casting and Rolling ofMagnesium Alloy AZ31 [Seite 441]
21.2 - Process Technology [Seite 447]
21.2.1 - Magnesium Twin-Roll Casting Benefits from Aluminium Heritage [Seite 448]
21.2.2 - Innovations in the Process Technology for Manufacturing Magnesium Alloy Sheet [Seite 454]
22 - Author Index [Seite 460]
23 - Subject Index [Seite 463]
