Repetitive impact loading strengthens commercial-purity titanium without losing ductility and strain-hardening capacity

Yuzhong Hui; Xianzhe Shi; Jianghua Shen

doi:10.1016/j.matlet.2026.140629

Repetitive impact loading strengthens commercial-purity titanium without losing ductility and strain-hardening capacity

Yuzhong Hui
, Xianzhe Shi
, Jianghua Shen

School of Aeronautics

Northwestern Polytechnical University Xian
Xi'an Technological University
National Key Laboratory of Strength and Structural Integrity

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

Abstract

Repetitive impact loading was employed to introduce high-density deformation twins in commercial-purity titanium. The yield strength is increased by 38% and the tensile strength by 17%, while the total ductility and strain-hardening capacity are fully preserved. Microstructural observations reveal that pre-existing twin boundaries promote twin boundary migration, secondary twinning, and additional activated slip systems. These deformation mechanisms compensate for the ductility loss associated with high dislocation density and effectively sustain the strain-hardening ability. This work provides a feasible strategy for achieving strength–ductility synergy in hexagonal close packed metals.

Original language	English
Article number	140629
Journal	Materials Letters
Volume	415
DOIs	https://doi.org/10.1016/j.matlet.2026.140629
State	Published - 15 Jul 2026

Keywords

Deformation twins
Impact loading
Microstructure
Strain hardening

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10.1016/j.matlet.2026.140629

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title = "Repetitive impact loading strengthens commercial-purity titanium without losing ductility and strain-hardening capacity",

abstract = "Repetitive impact loading was employed to introduce high-density deformation twins in commercial-purity titanium. The yield strength is increased by 38\% and the tensile strength by 17\%, while the total ductility and strain-hardening capacity are fully preserved. Microstructural observations reveal that pre-existing twin boundaries promote twin boundary migration, secondary twinning, and additional activated slip systems. These deformation mechanisms compensate for the ductility loss associated with high dislocation density and effectively sustain the strain-hardening ability. This work provides a feasible strategy for achieving strength–ductility synergy in hexagonal close packed metals.",

keywords = "Deformation twins, Impact loading, Microstructure, Strain hardening",

author = "Yuzhong Hui and Xianzhe Shi and Jianghua Shen",

note = "Publisher Copyright: {\textcopyright} 2026",

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doi = "10.1016/j.matlet.2026.140629",

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T1 - Repetitive impact loading strengthens commercial-purity titanium without losing ductility and strain-hardening capacity

AU - Hui, Yuzhong

AU - Shi, Xianzhe

AU - Shen, Jianghua

PY - 2026/7/15

Y1 - 2026/7/15

N2 - Repetitive impact loading was employed to introduce high-density deformation twins in commercial-purity titanium. The yield strength is increased by 38% and the tensile strength by 17%, while the total ductility and strain-hardening capacity are fully preserved. Microstructural observations reveal that pre-existing twin boundaries promote twin boundary migration, secondary twinning, and additional activated slip systems. These deformation mechanisms compensate for the ductility loss associated with high dislocation density and effectively sustain the strain-hardening ability. This work provides a feasible strategy for achieving strength–ductility synergy in hexagonal close packed metals.

AB - Repetitive impact loading was employed to introduce high-density deformation twins in commercial-purity titanium. The yield strength is increased by 38% and the tensile strength by 17%, while the total ductility and strain-hardening capacity are fully preserved. Microstructural observations reveal that pre-existing twin boundaries promote twin boundary migration, secondary twinning, and additional activated slip systems. These deformation mechanisms compensate for the ductility loss associated with high dislocation density and effectively sustain the strain-hardening ability. This work provides a feasible strategy for achieving strength–ductility synergy in hexagonal close packed metals.

KW - Deformation twins

KW - Impact loading

KW - Microstructure

KW - Strain hardening

UR - https://www.scopus.com/pages/publications/105035320285

U2 - 10.1016/j.matlet.2026.140629

DO - 10.1016/j.matlet.2026.140629

M3 - 文章

AN - SCOPUS:105035320285

SN - 0167-577X

VL - 415

JO - Materials Letters

JF - Materials Letters

M1 - 140629

ER -

Repetitive impact loading strengthens commercial-purity titanium without losing ductility and strain-hardening capacity

Abstract

Keywords

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