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Harnessing strengthening-metastability synergy for extreme work hardening in additively manufactured titanium alloys

Xuliang Chen, Youneng Xie, Tianlong Zhang, Zhihao Jiang, Xiangren Bai, Shun Xu, Jian Lu

2026Nature Communications6 citationsDOIOpen Access PDF

Abstract

Rapid bottom-up fabrication via additive manufacturing (AM) unlocks unprecedented design freedom for geometrically complex and lightweight titanium (Ti) alloys, a critical material for next-generation aerospace systems and 3C (computer, communication and consumer electronics) products. However, conventional AM Ti alloys face a persistent dilemma: achieving yield strengths above 1 GPa catastrophically degrades work hardening (typically < 2 GPa) and uniform ductility (< 5%). Here, we harness a strengthening-metastability synergy strategy via AM to demonstrate the powerful CoCrNi additive-strengthened Ti alloy with an outstanding combination of loss-free yield strength and drastically enhanced work hardening. Unlike traditional metastable alloys with incomplete phase transformation (β → β/α'), our design triggers a complete two-step martensitic transformation (β → β/α' → α'/α' twin) during deformation, without residual matrix and forming hierarchically mutual twin structures. This unique transformation pathway sustains a successive work hardening, achieving a record work hardening rate of 5.7 GPa and uniform elongation of 9.3% (triple that of base alloy), while maintaining 1030 MPa yield strength. The dual emphasis on synergy strategy and mechanistic innovation via the non-equilibrium AM process directly addresses the structural sector's urgent need for high-performance yet sustainable metallic solutions.

Topics & Concepts

Materials scienceTitanium alloyWork hardeningAlloyFabricationDiffusionless transformationDuctility (Earth science)AerospaceYield (engineering)Work (physics)MetallurgyShape-memory alloyHardening (computing)Strain hardening exponentTitaniumMartensiteResidual stressStructural materialComposite materialPlasticityStrengthening mechanisms of materialsForming processesMaterial DesignDeformation (meteorology)Crystal twinningElongationUltimate tensile strengthPhase (matter)Precipitation hardeningMicrostructureTitanium Alloys Microstructure and PropertiesAdditive Manufacturing Materials and ProcessesHigh Entropy Alloys Studies