Ultrastrong and ductile hierarchical heterostructured titanium composites from room to high temperatures

Shaolong Li; Shufeng Li; Huiying Liu; Lei Liu; Shaodi Wang; Dongxu Hui; Jie Yan; Rui zhou; Dingbo Tao; Wenfei Huang; Jianbo Gao; Xiaodong Hou; Xin Zhang; Bo Li; Zhimao Wang; Gang Li; Junhua Luan; Junko Umeda; Katsuyoshi Kondoh; Philip J. Withers; Yuntian Zhu

doi:10.1016/j.apmate.2025.100369

Ultrastrong and ductile hierarchical heterostructured titanium composites from room to high temperatures

Shaolong Li
, Shufeng Li
, Huiying Liu
, Lei Liu
, Shaodi Wang
, Dongxu Hui
, Jie Yan
, Rui zhou
, Dingbo Tao
, Wenfei Huang
, Jianbo Gao
, Xiaodong Hou
, Xin Zhang
, Bo Li
, Zhimao Wang
, Gang Li
, Junhua Luan
, Junko Umeda
, Katsuyoshi Kondoh
, Philip J. Withers

Yuntian Zhu

Xi'an University of Technology
City University of Hong Kong
Centre of Excellence for Advanced Materials
National Institute of Metrology China
CAS - Institute of High Energy Physics
The University of Osaka
University of Manchester

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

Titanium matrix composites (TMCs) offer significant enhancements in strength and heat resistance while preserving the low-density characteristic of advanced lightweight titanium alloys. However, ultra-strong, high-temperature TMCs are typically brittle at room temperature. Here, we overcome this limitation reporting a novel hierarchical, heterostructured design that achieving a 9.5% ductility —exceeding that of the TA15 matrix alloy—along with a remarkable tensile strength of nearly 1.4 GPa at room temperature and 700 MPa at 600 °C. This design forms hard, fine-grained regions homogeneously embedded within a soft, coarse-grained matrix. The hierarchical architecture facilitates the emergence of hetero-deformation-induced (HDI) stresses and strain partitioning, thereby enhancing strain hardening and dislocation activity. Our design strategy provides a pathway to achieving not only an optimal combination of strength-ductility at room-temperature but also exceptional high-temperature resistance.

Original language	English
Article number	100369
Journal	Advanced Powder Materials
Volume	5
Issue number	2
DOIs	https://doi.org/10.1016/j.apmate.2025.100369
State	Published - Apr 2026
Externally published	Yes

Keywords

Heterostructure
Mechanical properties
Powder metallurgy
Strengthening–toughening mechanism
Titanium matrix composites

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10.1016/j.apmate.2025.100369

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Li, S., Li, S., Liu, H., Liu, L., Wang, S., Hui, D., Yan, J., zhou, R., Tao, D., Huang, W., Gao, J., Hou, X., Zhang, X., Li, B., Wang, Z., Li, G., Luan, J., Umeda, J., Kondoh, K., ... Zhu, Y. (2026). Ultrastrong and ductile hierarchical heterostructured titanium composites from room to high temperatures. Advanced Powder Materials, 5(2), Article 100369. https://doi.org/10.1016/j.apmate.2025.100369

@article{66fdc4425ae146a5b2bc5e4646f621a2,

title = "Ultrastrong and ductile hierarchical heterostructured titanium composites from room to high temperatures",

abstract = "Titanium matrix composites (TMCs) offer significant enhancements in strength and heat resistance while preserving the low-density characteristic of advanced lightweight titanium alloys. However, ultra-strong, high-temperature TMCs are typically brittle at room temperature. Here, we overcome this limitation reporting a novel hierarchical, heterostructured design that achieving a 9.5\% ductility —exceeding that of the TA15 matrix alloy—along with a remarkable tensile strength of nearly 1.4 GPa at room temperature and 700 MPa at 600 °C. This design forms hard, fine-grained regions homogeneously embedded within a soft, coarse-grained matrix. The hierarchical architecture facilitates the emergence of hetero-deformation-induced (HDI) stresses and strain partitioning, thereby enhancing strain hardening and dislocation activity. Our design strategy provides a pathway to achieving not only an optimal combination of strength-ductility at room-temperature but also exceptional high-temperature resistance.",

keywords = "Heterostructure, Mechanical properties, Powder metallurgy, Strengthening–toughening mechanism, Titanium matrix composites",

author = "Shaolong Li and Shufeng Li and Huiying Liu and Lei Liu and Shaodi Wang and Dongxu Hui and Jie Yan and Rui zhou and Dingbo Tao and Wenfei Huang and Jianbo Gao and Xiaodong Hou and Xin Zhang and Bo Li and Zhimao Wang and Gang Li and Junhua Luan and Junko Umeda and Katsuyoshi Kondoh and Withers, \{Philip J.\} and Yuntian Zhu",

note = "Publisher Copyright: {\textcopyright} 2025 Central South University.",

year = "2026",

month = apr,

doi = "10.1016/j.apmate.2025.100369",

language = "英语",

volume = "5",

journal = "Advanced Powder Materials",

issn = "2772-834X",

publisher = "KeAi Communications Co.",

number = "2",

}

Li, S, Li, S, Liu, H, Liu, L, Wang, S, Hui, D, Yan, J, zhou, R, Tao, D, Huang, W, Gao, J, Hou, X, Zhang, X, Li, B, Wang, Z, Li, G, Luan, J, Umeda, J, Kondoh, K, Withers, PJ & Zhu, Y 2026, 'Ultrastrong and ductile hierarchical heterostructured titanium composites from room to high temperatures', Advanced Powder Materials, vol. 5, no. 2, 100369. https://doi.org/10.1016/j.apmate.2025.100369

TY - JOUR

T1 - Ultrastrong and ductile hierarchical heterostructured titanium composites from room to high temperatures

AU - Li, Shaolong

AU - Li, Shufeng

AU - Liu, Huiying

AU - Liu, Lei

AU - Wang, Shaodi

AU - Hui, Dongxu

AU - Yan, Jie

AU - zhou, Rui

AU - Tao, Dingbo

AU - Huang, Wenfei

AU - Gao, Jianbo

AU - Hou, Xiaodong

AU - Zhang, Xin

AU - Li, Bo

AU - Wang, Zhimao

AU - Li, Gang

AU - Luan, Junhua

AU - Umeda, Junko

AU - Kondoh, Katsuyoshi

AU - Withers, Philip J.

AU - Zhu, Yuntian

PY - 2026/4

Y1 - 2026/4

N2 - Titanium matrix composites (TMCs) offer significant enhancements in strength and heat resistance while preserving the low-density characteristic of advanced lightweight titanium alloys. However, ultra-strong, high-temperature TMCs are typically brittle at room temperature. Here, we overcome this limitation reporting a novel hierarchical, heterostructured design that achieving a 9.5% ductility —exceeding that of the TA15 matrix alloy—along with a remarkable tensile strength of nearly 1.4 GPa at room temperature and 700 MPa at 600 °C. This design forms hard, fine-grained regions homogeneously embedded within a soft, coarse-grained matrix. The hierarchical architecture facilitates the emergence of hetero-deformation-induced (HDI) stresses and strain partitioning, thereby enhancing strain hardening and dislocation activity. Our design strategy provides a pathway to achieving not only an optimal combination of strength-ductility at room-temperature but also exceptional high-temperature resistance.

AB - Titanium matrix composites (TMCs) offer significant enhancements in strength and heat resistance while preserving the low-density characteristic of advanced lightweight titanium alloys. However, ultra-strong, high-temperature TMCs are typically brittle at room temperature. Here, we overcome this limitation reporting a novel hierarchical, heterostructured design that achieving a 9.5% ductility —exceeding that of the TA15 matrix alloy—along with a remarkable tensile strength of nearly 1.4 GPa at room temperature and 700 MPa at 600 °C. This design forms hard, fine-grained regions homogeneously embedded within a soft, coarse-grained matrix. The hierarchical architecture facilitates the emergence of hetero-deformation-induced (HDI) stresses and strain partitioning, thereby enhancing strain hardening and dislocation activity. Our design strategy provides a pathway to achieving not only an optimal combination of strength-ductility at room-temperature but also exceptional high-temperature resistance.

KW - Heterostructure

KW - Mechanical properties

KW - Powder metallurgy

KW - Strengthening–toughening mechanism

KW - Titanium matrix composites

UR - https://www.scopus.com/pages/publications/105021470225

U2 - 10.1016/j.apmate.2025.100369

DO - 10.1016/j.apmate.2025.100369

M3 - 文章

AN - SCOPUS:105021470225

SN - 2772-834X

VL - 5

JO - Advanced Powder Materials

JF - Advanced Powder Materials

IS - 2

M1 - 100369

ER -

Ultrastrong and ductile hierarchical heterostructured titanium composites from room to high temperatures

Abstract

Keywords

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