Structure-property-functionality of bimetal interfaces

I. J. Beyerlein; N. A. Mara; J. Wang; J. S. Carpenter; S. J. Zheng; W. Z. Han; R. F. Zhang; K. Kang; T. Nizolek; T. M. Pollock

doi:10.1007/s11837-012-0431-0

Structure-property-functionality of bimetal interfaces

I. J. Beyerlein^*
, N. A. Mara
, J. Wang
, J. S. Carpenter
, S. J. Zheng
, W. Z. Han
, R. F. Zhang
, K. Kang
, T. Nizolek
, T. M. Pollock

^*Corresponding author for this work

Los Alamos National Laboratory
University of California at Santa Barbara

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

159 Scopus citations

Abstract

Interfaces, such as grain boundaries, phase boundaries, and surfaces, are important in materials of any microstructural size scale, whether the microstructure is coarse-grained, ultrafine-grained, or nano-grained. In nanostructured materials, however, they dominate material response and as we have seen many times over, can lead to extraordinary and unusual properties that far exceed those of their coarse-grained counterparts. In this article, we focus on bimetal interfaces. To best elucidate interface structure-property- functionality relationships, we focus our studies on simple layered composites composed of an alternating stack of two metals with bimetal interfaces spaced less than 100 nm. We fabricate these nanocomposites by either a bottom-up method (physical vapor deposition) or a top-down method (accumulative roll bonding) to produce two distinct interface types. Atomic-scale differences in interface structure are shown to result in profound effects on bulk-scale properties.

Original language	English
Pages (from-to)	1192-1207
Number of pages	16
Journal	JOM
Volume	64
Issue number	10
DOIs	https://doi.org/10.1007/s11837-012-0431-0
State	Published - Oct 2012
Externally published	Yes

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title = "Structure-property-functionality of bimetal interfaces",

abstract = "Interfaces, such as grain boundaries, phase boundaries, and surfaces, are important in materials of any microstructural size scale, whether the microstructure is coarse-grained, ultrafine-grained, or nano-grained. In nanostructured materials, however, they dominate material response and as we have seen many times over, can lead to extraordinary and unusual properties that far exceed those of their coarse-grained counterparts. In this article, we focus on bimetal interfaces. To best elucidate interface structure-property- functionality relationships, we focus our studies on simple layered composites composed of an alternating stack of two metals with bimetal interfaces spaced less than 100 nm. We fabricate these nanocomposites by either a bottom-up method (physical vapor deposition) or a top-down method (accumulative roll bonding) to produce two distinct interface types. Atomic-scale differences in interface structure are shown to result in profound effects on bulk-scale properties.",

author = "Beyerlein, \{I. J.\} and Mara, \{N. A.\} and J. Wang and Carpenter, \{J. S.\} and Zheng, \{S. J.\} and Han, \{W. Z.\} and Zhang, \{R. F.\} and K. Kang and T. Nizolek and Pollock, \{T. M.\}",

year = "2012",

month = oct,

doi = "10.1007/s11837-012-0431-0",

language = "英语",

volume = "64",

pages = "1192--1207",

journal = "JOM",

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}

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T1 - Structure-property-functionality of bimetal interfaces

AU - Beyerlein, I. J.

AU - Mara, N. A.

AU - Wang, J.

AU - Carpenter, J. S.

AU - Zheng, S. J.

AU - Han, W. Z.

AU - Zhang, R. F.

AU - Kang, K.

AU - Nizolek, T.

AU - Pollock, T. M.

PY - 2012/10

Y1 - 2012/10

N2 - Interfaces, such as grain boundaries, phase boundaries, and surfaces, are important in materials of any microstructural size scale, whether the microstructure is coarse-grained, ultrafine-grained, or nano-grained. In nanostructured materials, however, they dominate material response and as we have seen many times over, can lead to extraordinary and unusual properties that far exceed those of their coarse-grained counterparts. In this article, we focus on bimetal interfaces. To best elucidate interface structure-property- functionality relationships, we focus our studies on simple layered composites composed of an alternating stack of two metals with bimetal interfaces spaced less than 100 nm. We fabricate these nanocomposites by either a bottom-up method (physical vapor deposition) or a top-down method (accumulative roll bonding) to produce two distinct interface types. Atomic-scale differences in interface structure are shown to result in profound effects on bulk-scale properties.

AB - Interfaces, such as grain boundaries, phase boundaries, and surfaces, are important in materials of any microstructural size scale, whether the microstructure is coarse-grained, ultrafine-grained, or nano-grained. In nanostructured materials, however, they dominate material response and as we have seen many times over, can lead to extraordinary and unusual properties that far exceed those of their coarse-grained counterparts. In this article, we focus on bimetal interfaces. To best elucidate interface structure-property- functionality relationships, we focus our studies on simple layered composites composed of an alternating stack of two metals with bimetal interfaces spaced less than 100 nm. We fabricate these nanocomposites by either a bottom-up method (physical vapor deposition) or a top-down method (accumulative roll bonding) to produce two distinct interface types. Atomic-scale differences in interface structure are shown to result in profound effects on bulk-scale properties.

UR - https://www.scopus.com/pages/publications/84868516751

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DO - 10.1007/s11837-012-0431-0

M3 - 文章

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SN - 1047-4838

VL - 64

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EP - 1207

JO - JOM

JF - JOM

IS - 10

ER -

Structure-property-functionality of bimetal interfaces

Abstract

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