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Cryoforged nanotwinned titanium with ultrahigh strength and ductility

Shiteng Zhao, Ruopeng Zhang, Qin Yu, Jon Ell, Robert O. Ritchie, Andrew M. Minor

2021Science394 citationsDOI

Abstract

Nanostructured metals are usually strong because the ultrahigh density of internal boundaries restricts the mean free path of dislocations. Usually, they are also more brittle because of their diminished work-hardening ability. Nanotwinned materials, with coherent interfaces of mirror symmetry, can overcome this inherent trade-off. We show a bulk nanostructuring method that produces a multiscale, hierarchical twin architecture in a hexagonal closed-packed, solute-free, and coarse-grained titanium (Ti), with a substantial enhancement of tensile strength and ductility. Pure Ti achieved an ultimate tensile strength of almost 2 gigapascals and a true failure strain close to 100% at 77 kelvin. The multiscale twin structures are thermally stable up to 873 kelvin, which is above the critical temperature for many applications in extreme environments. Our results demonstrate a practical route to achieve attractive mechanical properties in Ti without involving exotic and often expensive alloying elements.

Topics & Concepts

Materials scienceBrittlenessUltimate tensile strengthDuctility (Earth science)TitaniumCrystal twinningTitanium alloyWork hardeningStrain hardening exponentComposite materialHexagonal crystal systemNanoscopic scaleNanotechnologyMetallurgyAlloyCrystallographyMicrostructureChemistryCreepMicrostructure and mechanical propertiesMetal and Thin Film MechanicsBoron and Carbon Nanomaterials Research
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