Effect of Solution Treatment on the Microstructure and Reverse Martensitic Transformation Behavior of a Novel Porous CuAlMn Shape Memory Alloy

Qing Zhou Wang; Chun Xiang Cui; Na Jun Yan; Qian Wang

doi:10.4028/www.scientific.net/AMR.421.173

Paper Titles

Fire Hazard Research of Aluminum Cable Joint
p.156

Melt Shearing Process for Recycling of Iron Contaminated Al-Si Alloy by Modification of Harmful Morphology of Intermetallics
p.160

Development of Software for Calculating Temperature Field by FEM Simulation to Hot Strip Mill
p.164

Molten Region around the Cavity Generated by a Moving Electron Beam
p.169

Effect of Solution Treatment on the Microstructure and Reverse Martensitic Transformation Behavior of a Novel Porous CuAlMn Shape Memory Alloy
p.173

Minimum Mould Exit Shell Thickness of Round Blooms for Peritectic Steel Casting
p.179

Residual Stress Simulation of a Single Bead-on-Plate with Modified High-Cr Ferrite Heat-Resistant Steel
p.184

Self-Assembly Fabrication of the Polymer p-n Junction Film
p.188

The Modeling and Simulation of Mirostrip Bandpass Filter Using ADS
p.192

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 421Effect of Solution Treatment on the Microstructure...

Effect of Solution Treatment on the Microstructure and Reverse Martensitic Transformation Behavior of a Novel Porous CuAlMn Shape Memory Alloy

Abstract:

A novel porous CuAlMn shape memory alloy (SMA) has been successfully fabricated by sintering-dissolution process. Effect of solution treatment on the microstructure and the reverse martensitic transformation (MT) behavior of the resulting specimens are investigated by means of SEM, optical microscope, DSC and internal friction (IF). The results show that with increasing solution temperature, the content and the size as well as the arrangement order of martensite in matrix increase. The reverse MT behavior follows different dependences on solution temperature and solution time at different temperature ranges. The related mechanisms are discussed in terms of the changes of the content of martensite and the concentration of quenched-in vacancies.