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Loss- free tensile ductility of dual- structure titanium composites via an interdiffusion and self- organization strategy

Liu, Lei and Li, Shufeng and Pan, Deng and Hui, Dongxu and Zhang, Xin and Li, Bo and Liang, Tianshou and Shi, Pengpeng and Bahador, Abdollah and Umeda, Junko and Kondoh, Katsuyoshi and Li, Shaolong and Gao, Lina and Wang, Zhimao and Li, Gang and Zhang, Shuyan and Wang, Ruihong and Chen, Wenge (2023) Loss- free tensile ductility of dual- structure titanium composites via an interdiffusion and self- organization strategy. Proceedings of the National Academy of Sciences of the United States of America, 120 (28). pp. 1-12. ISSN 0027-8424

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Official URL: http://dx.doi.org/10.1073/pnas.2302234120

Abstract

The deformation-coordination ability between ductile metal and brittle dispersive ceramic particles is poor, which means that an improvement in strength will inevitably sacrifice ductility in dispersion-strengthened metallic materials. Here, we present an inspired strategy for developing dual-structure-based titanium matrix composites (TMCs) that achieve 12.0% elongation comparable to the matrix Ti6Al4V alloys and enhanced strength compared to homostructure composites. The proposed dual-structure comprises a primary structure, namely, a TiB whisker-rich region engendered fine grain Ti6Al4V matrix with a three-dimensional micropellet architecture (3D-MPA), and an overall structure consisting of evenly distributed 3D-MPA “reinforcements” and a TiBw-lean titanium matrix. The dual structure presents a spatially heterogeneous grain distribution with 5.8 μm fine grains and 42.3 μm coarse grains, which exhibits excellent hetero-deformation-induced (HDI) hardening and achieves a 5.8% ductility. Interestingly, the 3D-MPA “reinforcements” show 11.1% isotropic deformability and 66% dislocation storage, which endows the TMCs with good strength and loss-free ductility. Our enlightening method uses an interdiffusion and self-organization strategy based on powder metallurgy to enable metal matrix composites with the heterostructure of the matrix and the configuration of reinforcement to address the strength-ductility trade-off dilemma.

Item Type:Article
Uncontrolled Keywords:dual structure, hetero-deformation-induced (HDI) hardening, interdiffusion, powder metallurgy, titanium matrix composites (TMCs)
Subjects:Q Science > Q Science (General)
Divisions:Razak School of Engineering and Advanced Technology
ID Code:106515
Deposited By: Yanti Mohd Shah
Deposited On:09 Jul 2024 06:25
Last Modified:09 Jul 2024 06:25

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