Role of interfaces in shock-induced plasticity in Cu/Nb nanolaminates

W. Z. Han; A. Misra; N. A. Mara; T. C. Germann; J. K. Baldwin; T. Shimada; S. N. Luo

doi:10.1080/14786435.2011.603706

Role of interfaces in shock-induced plasticity in Cu/Nb nanolaminates

W. Z. Han, A. Misra, N. A. Mara, T. C. Germann, J. K. Baldwin, T. Shimada, S. N. Luo

Chemical Engineering and Materials Science

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

64 Scopus citations

Abstract

We investigate deformation of pure Cu, pure Nb and 30nm Cu/30nm Nb nanolaminates induced by high strain rate shock loading. Abundant dislocation activities are observed in shocked pure Cu and Nb. In addition, a few deformation twins are found in the shocked pure Cu. In contrast, in shocked Cu/Nb nanolaminates, abundant deformation twins are found in the Cu layers, but only dislocations in the Nb layers. High resolution transmission electron microscopy reveals that the deformation twins in the Cu layers preferentially nucleate from the Cu(112)//Nb(112) interface habit planes rather than the predominant Cu(111)//Nb(110) interface planes. Our comparative study on the shock-induced plastic deformation of the pure metals (Cu and Nb) and the Cu/Nb nanolaminates underscores the critical role of heterogeneous phase interfaces in the dynamic deformation of multilayer materials.

Original language	English (US)
Pages (from-to)	4172-4185
Number of pages	14
Journal	Philosophical Magazine
Volume	91
Issue number	32
DOIs	https://doi.org/10.1080/14786435.2011.603706
State	Published - Nov 11 2011

Bibliographical note

Funding Information:
This work is sponsored by the US Department of Energy, Office of Science, Office of Basic Energy Sciences, Energy Frontier Research Center (EFRC) under Award No. 2008LANL1026.

Keywords

Cu/Nb nanolaminate
Deformation twinning
Interfaces
Shock loading

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title = "Role of interfaces in shock-induced plasticity in Cu/Nb nanolaminates",

abstract = "We investigate deformation of pure Cu, pure Nb and 30nm Cu/30nm Nb nanolaminates induced by high strain rate shock loading. Abundant dislocation activities are observed in shocked pure Cu and Nb. In addition, a few deformation twins are found in the shocked pure Cu. In contrast, in shocked Cu/Nb nanolaminates, abundant deformation twins are found in the Cu layers, but only dislocations in the Nb layers. High resolution transmission electron microscopy reveals that the deformation twins in the Cu layers preferentially nucleate from the Cu(112)//Nb(112) interface habit planes rather than the predominant Cu(111)//Nb(110) interface planes. Our comparative study on the shock-induced plastic deformation of the pure metals (Cu and Nb) and the Cu/Nb nanolaminates underscores the critical role of heterogeneous phase interfaces in the dynamic deformation of multilayer materials.",

keywords = "Cu/Nb nanolaminate, Deformation twinning, Interfaces, Shock loading",

author = "Han, {W. Z.} and A. Misra and Mara, {N. A.} and Germann, {T. C.} and Baldwin, {J. K.} and T. Shimada and Luo, {S. N.}",

note = "Funding Information: This work is sponsored by the US Department of Energy, Office of Science, Office of Basic Energy Sciences, Energy Frontier Research Center (EFRC) under Award No. 2008LANL1026.",

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AU - Han, W. Z.

AU - Misra, A.

AU - Mara, N. A.

AU - Germann, T. C.

AU - Baldwin, J. K.

AU - Shimada, T.

AU - Luo, S. N.

N1 - Funding Information: This work is sponsored by the US Department of Energy, Office of Science, Office of Basic Energy Sciences, Energy Frontier Research Center (EFRC) under Award No. 2008LANL1026.

PY - 2011/11/11

Y1 - 2011/11/11

N2 - We investigate deformation of pure Cu, pure Nb and 30nm Cu/30nm Nb nanolaminates induced by high strain rate shock loading. Abundant dislocation activities are observed in shocked pure Cu and Nb. In addition, a few deformation twins are found in the shocked pure Cu. In contrast, in shocked Cu/Nb nanolaminates, abundant deformation twins are found in the Cu layers, but only dislocations in the Nb layers. High resolution transmission electron microscopy reveals that the deformation twins in the Cu layers preferentially nucleate from the Cu(112)//Nb(112) interface habit planes rather than the predominant Cu(111)//Nb(110) interface planes. Our comparative study on the shock-induced plastic deformation of the pure metals (Cu and Nb) and the Cu/Nb nanolaminates underscores the critical role of heterogeneous phase interfaces in the dynamic deformation of multilayer materials.

AB - We investigate deformation of pure Cu, pure Nb and 30nm Cu/30nm Nb nanolaminates induced by high strain rate shock loading. Abundant dislocation activities are observed in shocked pure Cu and Nb. In addition, a few deformation twins are found in the shocked pure Cu. In contrast, in shocked Cu/Nb nanolaminates, abundant deformation twins are found in the Cu layers, but only dislocations in the Nb layers. High resolution transmission electron microscopy reveals that the deformation twins in the Cu layers preferentially nucleate from the Cu(112)//Nb(112) interface habit planes rather than the predominant Cu(111)//Nb(110) interface planes. Our comparative study on the shock-induced plastic deformation of the pure metals (Cu and Nb) and the Cu/Nb nanolaminates underscores the critical role of heterogeneous phase interfaces in the dynamic deformation of multilayer materials.

KW - Cu/Nb nanolaminate

KW - Deformation twinning

KW - Interfaces

KW - Shock loading

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Role of interfaces in shock-induced plasticity in Cu/Nb nanolaminates

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