第一性原理研究钛合金中的沉淀强化

Translated title of the contribution: Precipitation Strengthening in Titanium Alloys from First Principles Investigation

Kun Cheng, Shuming Chen, Shuo Cao, Jianrong Liu, Yingjie Ma, Qunbo Fan, Xingwang Cheng, Rui Yang, Qingmiao Hu*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

Abstract

Titanium alloys have shown wide application potential in the areas such as aerospace and marine because of their comprehensive properties, including high specific strength, ductility, corrosion resistance, and damage tolerance. Given the rapid development of new-generation advanced military hardware toward large scale, high-speed, light-weight, and structure-complicated titanium alloys experience increasingly harsh application environments. Thus, developing novel high-strength and high-toughness titanium alloys is an important direction in the field of titanium research. To date, the compositional design of titanium alloys is performed within the framework of some empirical rules without involving strengthening and toughening mechanisms. This kind of approach can hardly achieve an accurate and efficient material design. Based on the abovementioned background, the effect of alloying on the precipitation strengthening of the α + β dual-phase titanium alloy was studied by using the first-principles exact muffin-tin orbital method in combination with a coherent potential approximation. High-strength and high-toughness titanium alloys obtain its high strength through precipitation strengthening in the β-phase matrix with α-phase precipitates. The influence of alloying on the precipitation strengthening is crucial to the understanding and prediction of alloy strength and rational alloy design. In the present work, the elastic moduli and lattice constants of a serial binary titanium alloy Ti-xM (M = Al, V, Cr, Mn, Fe, Co, Ni, Nb, Mo, Ta, W) against the composition x were calculated using the first-principles method. Based on which, the elastic moduli of the titanium alloy with a complex composition (such as Ti-Al-V and Ti55521) were evaluated using the concept of elastic Mo equivalency. Subsequently, the precipitation strengthening of binary titanium alloys and the Ti55521 alloy was evaluated by using the elastic modulus within the framework of the modulus strengthening model. Result shows that alloying elements, such as Co, Fe, W, Mo, Ni, and Mn, have the strongest precipitation strengthening effect for the same particle size and volume fraction of α precipitates, followed by Cr, Nb, and Ta, whereas V is the weakest. The strengthening effect increases with the content of alloying element. For the Ti55521 alloy prepared by using a thermal mechanical process, subsequent short-time aging weakens the precipitation strengthening effect compared with long-time aging.

Translated title of the contributionPrecipitation Strengthening in Titanium Alloys from First Principles Investigation
Original languageChinese (Traditional)
Pages (from-to)537-547
Number of pages11
JournalJinshu Xuebao/Acta Metallurgica Sinica
Volume60
Issue number4
DOIs
Publication statusPublished - Apr 2024
Externally publishedYes

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Cheng, K., Chen, S., Cao, S., Liu, J., Ma, Y., Fan, Q., Cheng, X., Yang, R., & Hu, Q. (2024). 第一性原理研究钛合金中的沉淀强化. Jinshu Xuebao/Acta Metallurgica Sinica, 60(4), 537-547. https://doi.org/10.11900/0412.1961.2022.00096