Gradient cell–structured high-entropy alloy with exceptional strength and ductility | Zendy

Qingsong Pan | Zendy; Liangxue Zhang | Zendy; Rui Feng | Zendy; Qiuhong Lu | Zendy; Ke An | Zendy; Andrew Chihpin Chuang | Zendy; Jonathan D. Poplawsky | Zendy; Peter K. Liaw | Zendy; Lei Lu | Zendy

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Gradient cell–structured high-entropy alloy with exceptional strength and ductility

Author(s) -

Qingsong Pan,

Liangxue Zhang,

Rui Feng,

Qiuhong Lu,

Ke An,

Andrew Chihpin Chuang,

Jonathan D. Poplawsky,

Peter K. Liaw,

Lei Lu

Publication year - 2021

Publication title -

science

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 12.556

H-Index - 1186

eISSN - 1095-9203

pISSN - 0036-8075

DOI - 10.1126/science.abj8114

Subject(s) - materials science , plasticity , alloy , ductility (earth science) , high entropy alloys , dislocation , stacking , nanoscopic scale , strain hardening exponent , work hardening , composite material , microstructure , nanotechnology , creep , chemistry , organic chemistry

Strength by cyclic torsion For most alloys, conventional or high entropy, increasing strength comes at the cost of poor ductility. Although there are many strategies to break this inverse relationship, Panet al . now show that cyclic torsion on a high-entropy alloy enhances strength without degrading ductility (see the Perspective by Yeh). Cyclic torsion creates a gradient of dislocations and low-angle grain boundaries from the surface to the interior that organize into tiny stacking faults and twin when straining begins. These structures allow for the good ductility while simultaneously helping to work harden the alloy. —BG

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