Ductilization of High-Strength Magnesium Alloys

Abstract

A computational materials design approach is extended to high-strength Magnesium alloys to predict new compositions and novel multistep thermal processing to enhance ductility. Design modeling employing highly precise FLAPW all-electron DFT quantum mechanical calculations focus on the enhancement of grain boundary cohesion, based on the Rice-Wang thermodynamic model previously validated in high-performance steels. The calculations identify the cohesion enhancing potencies of grain boundary segregants as well as the segregation energies controlling grain boundary composition. The predicted surface thermodynamic parameters are integrated with bulk thermodynamics to predict novel alloy compositions and new thermal processing to optimize grain boundary composition in precipitation-strengthened alloys with enhanced ductility.

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Document Details

Document Type
Technical Report
Publication Date
Sep 17, 2012
Accession Number
ADA581756

Entities

People

  • Gregory B. Olson
  • Shengjun Zhang

Organizations

  • Northwestern University

Tags

Communities of Interest

  • Air Platforms
  • Energy and Power Technologies
  • Human Systems
  • Space

DTIC Thesaurus Topics

  • Corrosion Resistance
  • Crystal Structure
  • Embrittlement
  • Engineered Materials
  • Engineering
  • Ferrium
  • Materials
  • Materials Engineering
  • Materials Science
  • Materials Testing
  • Mechanical Properties
  • Mechanics
  • Solid Solutions
  • Solid State Physics
  • Stress Strain Relations
  • Stresses
  • Students

Fields of Study

  • Materials science

Readers

  • Powder metallurgy of Titanium alloys.
  • Quantum Chemistry

Technology Areas

  • Microelectronics
  • Quantum Computing