Abnormal strain hardening in nanostructured titanium at high strain rates and large strains

Y. M. Wang; J. Y. Huang; T. Jiao; Y. T. Zhu; A. V. Hamza

doi:10.1007/s10853-006-0822-0

Abnormal strain hardening in nanostructured titanium at high strain rates and large strains

Y. M. Wang^*, J. Y. Huang, T. Jiao, Y. T. Zhu, A. V. Hamza

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

41 Citations (Scopus)

Abstract

Commercial purity nanostructured titanium prepared by equal channel angular pressing plus cold rolling (grain size -260 nm) exhibits a nonnegligible strain hardening behavior at large compressive strains (>15%) and quasistatic loading conditions. The degree of the strain hardening increases with increasing strain rates and becomes more pronounced at dynamic loading rates. This behavior is in contrast with what we have seen so far in other nanostructured materials, where flat stress-strain curves are often seen. It was concluded from transmission electron microscopy investigations that in addition to dislocation slips, deformation twinning may have played a significant role in plastic deformation of nanostructured Ti. The structural failure behavior is in-situ recorded by a CCD camera and reasoned according to the microscopic observations. © Springer Science+Business Media, LLC 2007.

Original language	English
Pages (from-to)	1751-1756
Journal	Journal of Materials Science
Volume	42
Issue number	5
Online published	16 Dec 2006
DOIs	https://doi.org/10.1007/s10853-006-0822-0
Publication status	Published - Mar 2007
Externally published	Yes

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title = "Abnormal strain hardening in nanostructured titanium at high strain rates and large strains",

abstract = "Commercial purity nanostructured titanium prepared by equal channel angular pressing plus cold rolling (grain size -260 nm) exhibits a nonnegligible strain hardening behavior at large compressive strains (>15%) and quasistatic loading conditions. The degree of the strain hardening increases with increasing strain rates and becomes more pronounced at dynamic loading rates. This behavior is in contrast with what we have seen so far in other nanostructured materials, where flat stress-strain curves are often seen. It was concluded from transmission electron microscopy investigations that in addition to dislocation slips, deformation twinning may have played a significant role in plastic deformation of nanostructured Ti. The structural failure behavior is in-situ recorded by a CCD camera and reasoned according to the microscopic observations. {\textcopyright} Springer Science+Business Media, LLC 2007.",

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T1 - Abnormal strain hardening in nanostructured titanium at high strain rates and large strains

AU - Wang, Y. M.

AU - Huang, J. Y.

AU - Jiao, T.

AU - Zhu, Y. T.

AU - Hamza, A. V.

PY - 2007/3

Y1 - 2007/3

N2 - Commercial purity nanostructured titanium prepared by equal channel angular pressing plus cold rolling (grain size -260 nm) exhibits a nonnegligible strain hardening behavior at large compressive strains (>15%) and quasistatic loading conditions. The degree of the strain hardening increases with increasing strain rates and becomes more pronounced at dynamic loading rates. This behavior is in contrast with what we have seen so far in other nanostructured materials, where flat stress-strain curves are often seen. It was concluded from transmission electron microscopy investigations that in addition to dislocation slips, deformation twinning may have played a significant role in plastic deformation of nanostructured Ti. The structural failure behavior is in-situ recorded by a CCD camera and reasoned according to the microscopic observations. © Springer Science+Business Media, LLC 2007.

AB - Commercial purity nanostructured titanium prepared by equal channel angular pressing plus cold rolling (grain size -260 nm) exhibits a nonnegligible strain hardening behavior at large compressive strains (>15%) and quasistatic loading conditions. The degree of the strain hardening increases with increasing strain rates and becomes more pronounced at dynamic loading rates. This behavior is in contrast with what we have seen so far in other nanostructured materials, where flat stress-strain curves are often seen. It was concluded from transmission electron microscopy investigations that in addition to dislocation slips, deformation twinning may have played a significant role in plastic deformation of nanostructured Ti. The structural failure behavior is in-situ recorded by a CCD camera and reasoned according to the microscopic observations. © Springer Science+Business Media, LLC 2007.

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DO - 10.1007/s10853-006-0822-0

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JO - Journal of Materials Science

JF - Journal of Materials Science

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Abnormal strain hardening in nanostructured titanium at high strain rates and large strains

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