Reprint
Light Weight Alloys
Processing, Properties and Their Applications
Edited by
May 2020
238 pages
- ISBN978-3-03928-919-6 (Paperback)
- ISBN978-3-03928-920-2 (PDF)
This book is a reprint of the Special Issue Light Weight Alloys: Processing, Properties and Their Applications that was published in
Chemistry & Materials Science
Engineering
Summary
There is growing interest in light metallic alloys for a wide number of applications owing to their processing efficiency, processability, long service life, and environmental sustainability. Aluminum, magnesium, and titanium alloys are addressed in this Special Issue, however, the predominant role played by aluminum. The collection of papers published here covers a wide range of topics that generally characterize the performance of the alloys after manufacturing by conventional and innovative processing routes.
Format
- Paperback
License
© 2020 by the authors; CC BY-NC-ND license
Keywords
aluminum alloy; quenching process; material property; cooling rate; plastic strain; residual stress; 2024-T4 aluminum alloys; microarc oxidation; anode pulse-width; FEP; adhesion strength; wear resistance; titanium aluminides; hot compression; dynamic recrystallization; microstructure; Al alloy; remanufacturing; hot rolling; activation energy; alloy; 7XXX Al alloy; spray deposited; hot deformation behavior; precipitation; mechanical alloying; Al–Si alloy; mechanical properties; consolidation; Ti6Al4V titanium alloy; resistance spot welding; mechanical properties; microstructure; aluminum alloy; 7003 alloy; fatigue properties; thermomechanical treatment; fractography; magnesium alloy; compressive strength; hot workability; processing map; hot forging; Al-5Mg wire electrode; Zr; wire feedability; microstructure; mechanical properties; commercially pure titanium; rotary-die equal-channel angular pressing; cold rolling; ultra-fine grain; tensile property; creep; hot working; constitutive equations; solid solution hardening; high pressure die casting; Al-Si-Cu alloys; iron; sludge; intermetallics; fatigue behavior; high temperature; tensile properties; microstructural changes; AlSi9Cu3(Fe); AlSi11Cu2(Fe); AlSi12Cu1(Fe); hydroforming; springback; FEM simulation; UNS A92024-T3; hardening criteria; selective laser melting; AlSi10Mg alloy; processing temperature; aging treatment