Ultrahigh strength and ductility in newly developed materials with coherent nanolamellar architectures

AbstractNano-lamellar materials with ultrahigh strengths and unusual physical properties are of technological importance for structural applications. However, these materials generally suffer from low tensile ductility, which severely limits their practical utility. Here we show that markedly enhanced tensile ductility can be achieved in coherent nano-lamellar alloys, which exhibit an unprecedented combination of over 2 GPa yield strength and 16% uniform tensile ductility. The ultrahigh strength originates mainly from the lamellar boundary strengthening, whereas the large ductility correlates to a progressive work-hardening mechanism regulated by the unique nano-lamellar architecture. The coherent lamellar boundaries facilitate the dislocation transmission, which eliminates the stress concentrations at the boundaries. Meanwhile, deformation-induced hierarchical stacking-fault networks and associated high-density Lomer-Cottrell locks enhance the work hardening response, leading to unusually large tensile ductilities. The coherent nano-lamellar strategy can potentially be applied to many other alloys and open new avenues for designing ultrastrong yet ductile materials for technological applications.

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High ductility of ultrafine-grained steel via phase transformation

Journal of Materials Research ◽

10.1557/jmr.2008.0213 ◽

2008 ◽

Vol 23 (6) ◽

pp. 1578-1586 ◽

Cited By ~ 12

Author(s):

S. Cheng ◽

H. Choo ◽

Y.H. Zhao ◽

X-L. Wang ◽

Y.T. Zhu ◽

...

Keyword(s):

Phase Transformation ◽

Tensile Ductility ◽

High Strength ◽

Strain Rate Effect ◽

Inhomogeneous Deformation ◽

Ultrafine Grained ◽

Structural Applications ◽

Order Of Magnitude ◽

Strength And Ductility ◽

Ultrafine Grained Steel

There is often a tradeoff between strength and ductility, and the low ductility of ultrafine-grained (UFG) materials has been a major obstacle to their practical structural applications despite their high strength. In this study, we have achieved a ∼40% tensile ductility while increasing the yield strength of FeCrNiMn steel by an order of magnitude via grain refinement and deformation-induced martensitic phase transformation. The strain-rate effect on the inhomogeneous deformation behavior and phase transformation was studied in detail.

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Processing, Strength and Ductility of Bulk Nanostructured Metals Produced by Sever Plastic Deformation: An Overview

Materials Science Forum ◽

10.4028/www.scientific.net/msf.633-634.131 ◽

2009 ◽

Vol 633-634 ◽

pp. 131-150 ◽

Cited By ~ 1

Author(s):

A. Mashreghi ◽

L. Ghalandari ◽

M. Reihanian ◽

M.M. Moshksar

Keyword(s):

Plastic Deformation ◽

Nanocrystalline Metals ◽

Nanostructured Metals ◽

Ultrahigh Strength ◽

Nano Scale ◽

Ultrafine Grained ◽

Structural Applications ◽

Sever Plastic Deformation ◽

Processing Techniques ◽

Strength And Ductility

Nanostructured metals which have nano-scale microstructure are classified into ultrafine grained metals and nanocrystalline metals. In recent years, many processing techniques have been developed for producing nanostructured metals. Nanostructured metals possess ultrahigh strength but the low ductility is an important limitation on development of these materials for structural applications. This paper overviews various methods of producing nanostructured metals and recent investigations of strength and ductility of nanostructured metals processed by sever plastic deformation.

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Ultrafine grained Ti-based composites with ultrahigh strength and ductility achieved by equiaxing microstructure

Materials & Design (1980-2015) ◽

10.1016/j.matdes.2015.04.032 ◽

2015 ◽

Vol 79 ◽

pp. 1-5 ◽

Cited By ~ 69

Author(s):

L.H. Liu ◽

C. Yang ◽

F. Wang ◽

S.G. Qu ◽

X.Q. Li ◽

...

Keyword(s):

Ultrahigh Strength ◽

Ultrafine Grained ◽

Strength And Ductility

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Tensile Deformation Behavior and Work Hardening Mechanism of Fe–28Mn–9Al–0.4C and Fe–28Mn–9Al–1C Alloys

Materials Transactions JIM ◽

10.2320/matertrans1989.38.112 ◽

1997 ◽

Vol 38 (2) ◽

pp. 112-118 ◽

Cited By ~ 19

Author(s):

S. C. Tjong ◽

S. M. Zhu

Keyword(s):

Work Hardening ◽

Deformation Behavior ◽

Tensile Deformation ◽

Hardening Mechanism ◽

Tensile Deformation Behavior

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Work-Hardening Mechanism during Super-Heavy Plastic Deformation in Mechanically Milled Iron Powder

Materials Transactions JIM ◽

10.2320/matertrans1989.40.1149 ◽

1999 ◽

Vol 40 (10) ◽

pp. 1149-1157 ◽

Cited By ~ 46

Author(s):

Yuuji Kimura ◽

Hideyuki Hidaka ◽

Setsuo Takaki

Keyword(s):

Plastic Deformation ◽

Iron Powder ◽

Work Hardening ◽

Hardening Mechanism

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Wear behavior and subsurface layer work hardening mechanism of Fe-24.1Mn-1.21C-0.48Si steel

Procedia Engineering ◽

10.1016/j.proeng.2017.10.990 ◽

2017 ◽

Vol 207 ◽

pp. 2251-2256 ◽

Cited By ~ 4

Author(s):

Changhong Cai ◽

Renbo Song ◽

Shuai Liu ◽

Yifan Feng ◽

Zhongzheng Pei

Keyword(s):

Work Hardening ◽

Wear Behavior ◽

Subsurface Layer ◽

Hardening Mechanism

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A novel work hardening mechanism of nanoscale materials by grain boundary transformation

Acta Materialia ◽

10.1016/j.actamat.2021.117536 ◽

2021 ◽

pp. 117536

Author(s):

Tomotsugu Shimokawa ◽

Tomoaki Niiyama ◽

Tomoya Miyaki ◽

Munefusa Ikeda ◽

Kenji Higashida

Keyword(s):

Grain Boundary ◽

Work Hardening ◽

Nanoscale Materials ◽

Hardening Mechanism

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Effects of impact energy on the wear resistance and work hardening mechanism of medium manganese austenitic steel

Friction ◽

10.1007/s40544-017-0158-6 ◽

2017 ◽

Vol 5 (4) ◽

pp. 447-454 ◽

Cited By ~ 4

Author(s):

Hui Chen ◽

Dong Zhao ◽

Qingliang Wang ◽

Yinghuai Qiang ◽

Jianwei Qi

Keyword(s):

Wear Resistance ◽

Austenitic Steel ◽

Impact Energy ◽

Work Hardening ◽

Hardening Mechanism

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Capturing and Micromechanical Analysis of the Crack-Branching Behavior in Welded Joints

Metals ◽

10.3390/met10101308 ◽

2020 ◽

Vol 10 (10) ◽

pp. 1308

Author(s):

Wenjie Wang ◽

Jie Yang ◽

Haofeng Chen ◽

Qianyu Yang

Keyword(s):

Crack Propagation ◽

Welded Joints ◽

High Stress ◽

High Strength ◽

Crack Branching ◽

Stress Concentrations ◽

Ductile Materials ◽

Pulling Forces ◽

Crack Propagation Process ◽

Combined Action

During the crack propagation process, the crack-branching behavior makes fracture more unpredictable. However, compared with the crack-branching behavior that occurs in brittle materials or ductile materials under dynamic loading, the branching behavior has been rarely reported in welded joints under quasi-static loading. Understanding the branching criterion or the mechanism governing the bifurcation of a crack in welded joints is still a challenge. In this work, three kinds of crack-branching models that reflect simplified welded joints were designed, and the aim of the present paper is to find and capture the crack-branching behavior in welded joints and to shed light on its branching mechanism. The results show that as long as there is another large enough propagation trend that is different from the original crack propagation direction, then crack-branching behavior occurs. A high strength mismatch that is induced by both the mechanical properties and dimensions of different regions is the key of crack branching in welded joints. Each crack branching is accompanied by three local high stress concentrations at the crack tip. Three pulling forces that are created by the three local high stress concentrations pull the crack, which propagates along with the directions of stress concentrations. Under the combined action of the three pulling forces, crack branching occurs, and two new cracks initiate from the middle of the pulling forces.

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