TiAl Alloy Spark Plasma Sintered from Mechanically Activated Powders

Zhi Wei Wang; Jun Chen

doi:10.4028/www.scientific.net/AMR.284-286.2336

Paper Titles

Reduced-Pressure Melts Growth of the Vacuum Ultraviolet Double Frequency Crystal KBe₂BO₃F₂ (KBBF)
p.2315

A New Structure of the 2D Photonic Crystal Microcavities with Hexagonal Lattice
p.2319

Composition and Properties of Phosphate Cement
p.2327

MCM-41 Anchored Manganese Salen Complex as Catalysts for Cyclohexene Oxidation
p.2331

TiAl Alloy Spark Plasma Sintered from Mechanically Activated Powders
p.2336

Research and Application of Lost Foam Technology of Goods Train Low-Carbon Alloy Steel Casting
p.2340

The Analysis of Toy Design Factor for Customer Loyalty in Taiwan
p.2350

Effect of Deformation on the Austenite to Pearlite Transformation
p.2358

Analysis of Microstructure of Phosphate Cement
p.2366

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 284-286TiAl Alloy Spark Plasma Sintered from Mechanically...

TiAl Alloy Spark Plasma Sintered from Mechanically Activated Powders

Abstract:

Powder of Ti-46at%Al alloy was synthesized through mechanical activation (MA) and then sintered and concurrently consolidated in a short sintering time of 900 s by using spark plasma sintering (SPS) process. The XRD and SEM profiles show that the microstructures of TiAl alloys contained γ TiAl and small amount α-2 Ti₃Al phase, whose amount can be controlled by the sintering temperature. The compacts retained the original fine-grained fully densified bodies by avoiding an excessively high sintering temperature. The alloys sintered at higher temperature with this process showed a coarser microstructure. So it is possible to produce dense nanostructured TiAl alloys by mechanically activated spark plasma sintering (MASPS) within a very short period of time.