A transforming metal nanocomposite with large elastic strain, low modulus, and high strength

Shijie Hao; Lishan Cui; Daqiang Jiang; Xiaodong Han; Yang Ren; Jiang Jiang; Yinong Liu; Zhenyang Liu; Shengcheng Mao; Yandong Wang; Yan Li; Xiaobing Ren; Xiangdong Ding; Shan Wang; Cun Yu; Xiaobin Shi; Minshu Du; Feng Yang; Yanjun Zheng; Ze Zhang; Xiaodong Li; Dennis E. Brown; Ju Li

doi:10.1126/science.1228602

A transforming metal nanocomposite with large elastic strain, low modulus, and high strength

Shijie Hao
, Lishan Cui^*
, Daqiang Jiang
, Xiaodong Han
, Yang Ren
, Jiang Jiang
, Yinong Liu
, Zhenyang Liu
, Shengcheng Mao
, Yandong Wang
, Yan Li
, Xiaobing Ren
, Xiangdong Ding
, Shan Wang
, Cun Yu
, Xiaobin Shi
, Minshu Du
, Feng Yang
, Yanjun Zheng
, Ze Zhang

Xiaodong Li, Dennis E. Brown, Ju Li

^*Corresponding author for this work

School of Materials Science and Engineering

China University of Petroleum - Beijing
Beijing University of Technology
Argonne National Laboratory
University of Western Australia
University of Science and Technology Beijing
Xi'an Jiaotong University
National Institute for Materials Science Tsukuba
Zhejiang University
University of South Carolina
Northern Illinois University
Massachusetts Institute of Technology

Research output: Contribution to journal › Article › peer-review

315 Scopus citations

Abstract

Freestanding nanowires have ultrahigh elastic strain limits (4 to 7%) and yield strengths, but exploiting their intrinsic mechanical properties in bulk composites has proven to be difficult. We exploited the intrinsic mechanical properties of nanowires in a phase-transforming matrix based on the concept of elastic and transformation strain matching. By engineering the microstructure and residual stress to couple the true elasticity of Nb nanowires with the pseudoelasticity of a NiTi shape-memory alloy, we developed an in situ composite that possesses a large quasi-linear elastic strain of over 6%, a low Young's modulus of ∼28 gigapascals, and a high yield strength of ∼1.65 gigapascals. Our elastic strain-matching approach allows the exceptional mechanical properties of nanowires to be exploited in bulk materials.

Original language	English
Pages (from-to)	1191-1194
Number of pages	4
Journal	Science
Volume	339
Issue number	6124
DOIs	https://doi.org/10.1126/science.1228602
State	Published - 8 Mar 2013

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10.1126/science.1228602

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@article{a011da87ae8242d9b74ea8ddbbb53e59,

title = "A transforming metal nanocomposite with large elastic strain, low modulus, and high strength",

abstract = "Freestanding nanowires have ultrahigh elastic strain limits (4 to 7\%) and yield strengths, but exploiting their intrinsic mechanical properties in bulk composites has proven to be difficult. We exploited the intrinsic mechanical properties of nanowires in a phase-transforming matrix based on the concept of elastic and transformation strain matching. By engineering the microstructure and residual stress to couple the true elasticity of Nb nanowires with the pseudoelasticity of a NiTi shape-memory alloy, we developed an in situ composite that possesses a large quasi-linear elastic strain of over 6\%, a low Young's modulus of ∼28 gigapascals, and a high yield strength of ∼1.65 gigapascals. Our elastic strain-matching approach allows the exceptional mechanical properties of nanowires to be exploited in bulk materials.",

author = "Shijie Hao and Lishan Cui and Daqiang Jiang and Xiaodong Han and Yang Ren and Jiang Jiang and Yinong Liu and Zhenyang Liu and Shengcheng Mao and Yandong Wang and Yan Li and Xiaobing Ren and Xiangdong Ding and Shan Wang and Cun Yu and Xiaobin Shi and Minshu Du and Feng Yang and Yanjun Zheng and Ze Zhang and Xiaodong Li and Brown, \{Dennis E.\} and Ju Li",

year = "2013",

month = mar,

day = "8",

doi = "10.1126/science.1228602",

language = "英语",

volume = "339",

pages = "1191--1194",

journal = "Science",

issn = "0036-8075",

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

number = "6124",

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Hao, S, Cui, L, Jiang, D, Han, X, Ren, Y, Jiang, J, Liu, Y, Liu, Z, Mao, S, Wang, Y, Li, Y, Ren, X, Ding, X, Wang, S, Yu, C, Shi, X, Du, M, Yang, F, Zheng, Y, Zhang, Z, Li, X, Brown, DE & Li, J 2013, 'A transforming metal nanocomposite with large elastic strain, low modulus, and high strength', Science, vol. 339, no. 6124, pp. 1191-1194. https://doi.org/10.1126/science.1228602

TY - JOUR

T1 - A transforming metal nanocomposite with large elastic strain, low modulus, and high strength

AU - Hao, Shijie

AU - Cui, Lishan

AU - Jiang, Daqiang

AU - Han, Xiaodong

AU - Ren, Yang

AU - Jiang, Jiang

AU - Liu, Yinong

AU - Liu, Zhenyang

AU - Mao, Shengcheng

AU - Wang, Yandong

AU - Li, Yan

AU - Ren, Xiaobing

AU - Ding, Xiangdong

AU - Wang, Shan

AU - Yu, Cun

AU - Shi, Xiaobin

AU - Du, Minshu

AU - Yang, Feng

AU - Zheng, Yanjun

AU - Zhang, Ze

AU - Li, Xiaodong

AU - Brown, Dennis E.

AU - Li, Ju

PY - 2013/3/8

Y1 - 2013/3/8

N2 - Freestanding nanowires have ultrahigh elastic strain limits (4 to 7%) and yield strengths, but exploiting their intrinsic mechanical properties in bulk composites has proven to be difficult. We exploited the intrinsic mechanical properties of nanowires in a phase-transforming matrix based on the concept of elastic and transformation strain matching. By engineering the microstructure and residual stress to couple the true elasticity of Nb nanowires with the pseudoelasticity of a NiTi shape-memory alloy, we developed an in situ composite that possesses a large quasi-linear elastic strain of over 6%, a low Young's modulus of ∼28 gigapascals, and a high yield strength of ∼1.65 gigapascals. Our elastic strain-matching approach allows the exceptional mechanical properties of nanowires to be exploited in bulk materials.

AB - Freestanding nanowires have ultrahigh elastic strain limits (4 to 7%) and yield strengths, but exploiting their intrinsic mechanical properties in bulk composites has proven to be difficult. We exploited the intrinsic mechanical properties of nanowires in a phase-transforming matrix based on the concept of elastic and transformation strain matching. By engineering the microstructure and residual stress to couple the true elasticity of Nb nanowires with the pseudoelasticity of a NiTi shape-memory alloy, we developed an in situ composite that possesses a large quasi-linear elastic strain of over 6%, a low Young's modulus of ∼28 gigapascals, and a high yield strength of ∼1.65 gigapascals. Our elastic strain-matching approach allows the exceptional mechanical properties of nanowires to be exploited in bulk materials.

UR - https://www.scopus.com/pages/publications/84874749588

U2 - 10.1126/science.1228602

DO - 10.1126/science.1228602

M3 - 文章

AN - SCOPUS:84874749588

SN - 0036-8075

VL - 339

SP - 1191

EP - 1194

JO - Science

JF - Science

IS - 6124

ER -

A transforming metal nanocomposite with large elastic strain, low modulus, and high strength

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