Ductilization of 2.6-GPa alloys via short-range ordered interfaces and supranano precipitates

Yong Qiang Yan; Wen Hao Cha; Sida Liu; Yan Ma; Jun Hua Luan; Ziyuan Rao; Chang Liu; Zhi Wei Shan; Jian Lu; Ge Wu

doi:10.1126/science.adr4917

Ductilization of 2.6-GPa alloys via short-range ordered interfaces and supranano precipitates

Yong Qiang Yan, Wen Hao Cha, Sida Liu, Yan Ma, Jun Hua Luan, Ziyuan Rao, Chang Liu, Zhi Wei Shan, Jian Lu, Ge Wu

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Abstract

Higher strength and higher ductility are desirable for structural materials. However, ultrastrong alloys inevitably show decreased strain-hardening capacity, limiting their uniform elongation. We present a supranano (<10 nanometers) and short-range ordering design for grain interiors and grain boundary regions, respectively, in fine-grained alloys based on vanadium, cobalt, and nickel, with additions of tungsten, copper, aluminum, and boron. The pronounced grain boundary-related strengthening and ductilization mechanism is realized through segregation of the short-range ordering near the grain boundary. Furthermore, the supranano ordering with a larger size has an enhanced pinning effect for dislocations and stacking faults, multiplied and accumulated in grain interiors during plastic deformation. These mechanisms promote continuously increased flow stress until fracture of the alloy at 10% strain with 2.6-gigapascal tensile stress.

Original language	English
Pages (from-to)	401-406
Number of pages	6
Journal	Science (New York, N.Y.)
Volume	387
Issue number	6732
DOIs	https://doi.org/10.1126/science.adr4917
Publication status	Published - 2025

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title = "Ductilization of 2.6-GPa alloys via short-range ordered interfaces and supranano precipitates",

abstract = "Higher strength and higher ductility are desirable for structural materials. However, ultrastrong alloys inevitably show decreased strain-hardening capacity, limiting their uniform elongation. We present a supranano (<10 nanometers) and short-range ordering design for grain interiors and grain boundary regions, respectively, in fine-grained alloys based on vanadium, cobalt, and nickel, with additions of tungsten, copper, aluminum, and boron. The pronounced grain boundary-related strengthening and ductilization mechanism is realized through segregation of the short-range ordering near the grain boundary. Furthermore, the supranano ordering with a larger size has an enhanced pinning effect for dislocations and stacking faults, multiplied and accumulated in grain interiors during plastic deformation. These mechanisms promote continuously increased flow stress until fracture of the alloy at 10% strain with 2.6-gigapascal tensile stress.",

author = "Yan, {Yong Qiang} and Cha, {Wen Hao} and Sida Liu and Yan Ma and Luan, {Jun Hua} and Ziyuan Rao and Chang Liu and Shan, {Zhi Wei} and Jian Lu and Ge Wu",

year = "2025",

doi = "10.1126/science.adr4917",

language = "English",

volume = "387",

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journal = "Science (New York, N.Y.)",

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publisher = "American Association for the Advancement of Science",

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TY - JOUR

T1 - Ductilization of 2.6-GPa alloys via short-range ordered interfaces and supranano precipitates

AU - Yan, Yong Qiang

AU - Cha, Wen Hao

AU - Liu, Sida

AU - Ma, Yan

AU - Luan, Jun Hua

AU - Rao, Ziyuan

AU - Liu, Chang

AU - Shan, Zhi Wei

AU - Lu, Jian

AU - Wu, Ge

PY - 2025

Y1 - 2025

N2 - Higher strength and higher ductility are desirable for structural materials. However, ultrastrong alloys inevitably show decreased strain-hardening capacity, limiting their uniform elongation. We present a supranano (<10 nanometers) and short-range ordering design for grain interiors and grain boundary regions, respectively, in fine-grained alloys based on vanadium, cobalt, and nickel, with additions of tungsten, copper, aluminum, and boron. The pronounced grain boundary-related strengthening and ductilization mechanism is realized through segregation of the short-range ordering near the grain boundary. Furthermore, the supranano ordering with a larger size has an enhanced pinning effect for dislocations and stacking faults, multiplied and accumulated in grain interiors during plastic deformation. These mechanisms promote continuously increased flow stress until fracture of the alloy at 10% strain with 2.6-gigapascal tensile stress.

AB - Higher strength and higher ductility are desirable for structural materials. However, ultrastrong alloys inevitably show decreased strain-hardening capacity, limiting their uniform elongation. We present a supranano (<10 nanometers) and short-range ordering design for grain interiors and grain boundary regions, respectively, in fine-grained alloys based on vanadium, cobalt, and nickel, with additions of tungsten, copper, aluminum, and boron. The pronounced grain boundary-related strengthening and ductilization mechanism is realized through segregation of the short-range ordering near the grain boundary. Furthermore, the supranano ordering with a larger size has an enhanced pinning effect for dislocations and stacking faults, multiplied and accumulated in grain interiors during plastic deformation. These mechanisms promote continuously increased flow stress until fracture of the alloy at 10% strain with 2.6-gigapascal tensile stress.

UR - http://www.scopus.com/inward/record.url?scp=85216718196&partnerID=8YFLogxK

U2 - 10.1126/science.adr4917

DO - 10.1126/science.adr4917

M3 - Article

C2 - 39847626

AN - SCOPUS:85216718196

SN - 0036-8075

VL - 387

SP - 401

EP - 406

JO - Science (New York, N.Y.)

JF - Science (New York, N.Y.)

IS - 6732

ER -

Ductilization of 2.6-GPa alloys via short-range ordered interfaces and supranano precipitates

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