TY - JOUR
T1 - Heterogeneous precipitate microstructure in titanium alloys for simultaneous improvement of strength and ductility
AU - Hao, Mengyuan
AU - Li, Pei
AU - Li, Xuexiong
AU - Zhang, Tianlong
AU - Wang, Dong
AU - Sun, Qiaoyan
AU - Liu, Libin
AU - Li, Jinshan
AU - Cui, Yuyou
AU - Yang, Rui
AU - Xu, Dongsheng
N1 - Publisher Copyright:
© 2022
PY - 2022/10/10
Y1 - 2022/10/10
N2 - The design of alloys with simultaneous high strength and high ductility is still a difficult challenge. Here, we propose a new approach to designing multi-phase alloys with a synergistic combination of strength and ductility by engineering heterogeneous precipitate microstructures through the activation of different transformation mechanisms. Using a two-phase titanium alloy as an example, phase field simulations are carried out firstly to design heat treatment schedules that involve both conventional nucleation and growth and non-conventional pseudospinodal decomposition mechanisms, and the calculated microstructures have been evaluated by crystal plasticity finite element modeling. According to simulations, we then set a two-step heat treatment to produce bimodal α+β microstructure in Ti-10V-2Fe-3Al. Further mechanical testing shows that the ductility of the alloy is increased by ∼50% and the strength is increased by ∼10% as compared to its unimodal counterpart. Our work may provide a general way to improve the mechanical properties of alloys through multiscale microstructure design.
AB - The design of alloys with simultaneous high strength and high ductility is still a difficult challenge. Here, we propose a new approach to designing multi-phase alloys with a synergistic combination of strength and ductility by engineering heterogeneous precipitate microstructures through the activation of different transformation mechanisms. Using a two-phase titanium alloy as an example, phase field simulations are carried out firstly to design heat treatment schedules that involve both conventional nucleation and growth and non-conventional pseudospinodal decomposition mechanisms, and the calculated microstructures have been evaluated by crystal plasticity finite element modeling. According to simulations, we then set a two-step heat treatment to produce bimodal α+β microstructure in Ti-10V-2Fe-3Al. Further mechanical testing shows that the ductility of the alloy is increased by ∼50% and the strength is increased by ∼10% as compared to its unimodal counterpart. Our work may provide a general way to improve the mechanical properties of alloys through multiscale microstructure design.
KW - Crystal plasticity finite element
KW - Multiscale heterogeneous microstructure
KW - Phase field simulation
KW - Pseudospinodal decomposition mechanisms
KW - Titanium alloys
KW - Two-step aging
UR - https://www.webofscience.com/wos/woscc/full-record/WOS:000788165000007
UR - https://openalex.org/W4226245826
UR - https://www.scopus.com/pages/publications/85128236050
U2 - 10.1016/j.jmst.2022.02.025
DO - 10.1016/j.jmst.2022.02.025
M3 - Journal Article
SN - 1005-0302
VL - 124
SP - 150
EP - 163
JO - Journal of Materials Science and Technology
JF - Journal of Materials Science and Technology
ER -