Metallurgical Abstracts on Light Metals and Alloys vol.55
Effect of Lamellar Spacing on Creep Strength of α-Mg/C14-Mg2Ca Eutectic Alloy
Koji Oishi*, Satoshi Araki* and Yoshihiro Terada*
*Department of Materials Science and Engineering, Tokyo Institute of Technology
[Published in Materials Transactions, Vol. 62 (2021), pp. 1414–1419]
https://doi.org/10.2320/matertrans.MT-M2021101
E-mail: terada.y.ab[at]m.titech.ac.jp
Key Words: magnesium-calcium alloy, lamellar spacing, interface, creep, dislocation
In tensile tests, α-Mg/C14-Mg2Ca eutectic alloy with a lamellar structure is plastically deformed above 473 K but ruptures before yielding at temperatures below 423 K. This study investigates the effect of the α/C14 interface on the creep strength of α-Mg/C14-Mg2Ca eutectic alloy at 473 K under 40 MPa stress. The creep curves of the alloy exhibited three stages: a normal transient creep stage, minimum creep-rate stage, and accelerating stage. The minimum creep rate was proportional to the lamellar spacing, indicating that the α/C14 lamellar interface plays a creep-strengthening role. In high-resolution transmission electron microscope observations of the specimens after the creep test, a dislocations appeared within the α-Mg lamellae and were randomly distributed on the α/C14 interface. It was deduced that the α/C14 interface presents a barrier to dislocation glide and does not annihilate and/or rearrange its dislocation caused by the creep test.
Fig. HRTEM image, taken with B = [01-11]α, of the α/C14 lamellar interface for the 723 K/1 h-aged α-Mg/C14-Mg2Ca eutectic alloy crept at 473 K under a stress of 40 MPa, where the creep test was interrupted at a strain of 1.3%.