Microstructural Evolution in Rapidly Solidified Cu-Nb Powders

Abstract

High pressure inert gas atomization has been used to produce rapidly solidification Cu-21.2wt% Nb powders with a range of particle sizes and microstructures. The associated microstructures depend on particle size. Specifically, fine-scale particles are characterized by a predominance of Nb- rich, multiphase spheroids and a small population of nearly pure Nb dendrites in an almost pure matrix of Cu. In contrast, large particles contain only Nb dendrites in a Cu matrix. The volume fraction of 'second phase' is much lower in the latter instance than in the former. The change in microstructure with particle size is believed to be a result of both the amount of undercooling and cooling rate of the liquid droplets prior to and during solidification. In particular, the large undercoolings in the fine particles are believed to induce a non-equilibrium liquid phase separation which results in a high volume fraction of spheroidal, multiphase Nb-Cu particles within a Cu-rich matrix containing Nb dendrites. Keywords: Gas atomization, Rapid solidification, Cu-Nb Alloys, Undercooling, Cooling rate, Microstructure.

Open PDF

Document Details

Document Type
Technical Report
Publication Date
Aug 22, 1990
Accession Number
ADA225860

Entities

People

  • Donald A. Koss
  • I. E. Anderson
  • K. L. Zeik
  • P. R. Howell

Organizations

  • Pennsylvania State University

Tags

Communities of Interest

  • Energy and Power Technologies

DTIC Thesaurus Topics

  • Atomization
  • Chemical Analysis
  • Cooling
  • Electron Microscopes
  • Engineering
  • High Pressure
  • Liquid Phases
  • Materials
  • Materials Engineering
  • Materials Science
  • Particle Size
  • Particles
  • Pennsylvania
  • Phase
  • Phase Diagrams
  • Phase Separation
  • Supercooling

Fields of Study

  • Materials science

Readers

  • Aerosol Science/Aerosol Physics
  • Powder metallurgy of Titanium alloys.