The influence of rolling schedule on the dynamic properties of accumulatively roll bonded nano-layered Cu-Nb

Ellen K. Cerreta; Weizhong Han; Nathan A. Mara; Irene J. Beyerlein; John S. Carpenter; Shijian Zheng; Carl P. Trujillo; Patricia O. Dickerson; Amit Misra

doi:10.4028/www.scientific.net/KEM.622-623.1031

The influence of rolling schedule on the dynamic properties of accumulatively roll bonded nano-layered Cu-Nb

Ellen K. Cerreta
, Weizhong Han
, Nathan A. Mara
, Irene J. Beyerlein
, John S. Carpenter
, Shijian Zheng
, Carl P. Trujillo
, Patricia O. Dickerson
, Amit Misra

材料科学与工程学院

Computational Earth Science, Earth and Environmental Sciences Division, Los Alamos National Laboratory

科研成果: 书/报告/会议事项章节 › 会议稿件 › 同行评审

摘要

Cu-Nb nano-layered material was produced through an accumulative roll bonding (ARB) technique. Using this technique, two different rolling schedules were employed to produce a normal and transverse rolled material. This resulted in specimens with differing microstructures within the 135nm thick nano-layers and interface structures between the layers. The dynamic response of these bulk Cu-Nb nanocomposites was then investigated under planar shock loading. It was observed in dynamically fractured specimens that the characteristics of ductile failure features formed on the fracture surface after dynamic loading were dependent upon the processing route of the nanocomposite. Specifically, grain shape differences due to dissimilar rolling passes are linked with differences in the failure response, particularly kinetics of fracture. In addition, incipient failure immediately below the primary fracture surface was also observed. Numerous nanovoids were nucleated and aligned linearly in the middle of Cu layers within the shocked Cu-Nb nanocomposites. These observations indicate relative stability of Cu-Nb interfaces produced by the ARB methods utilized in this study under dynamic loading conditions.

源语言	英语
主期刊名	Metal Forming 2014
编辑	Fabrizio Micari, Livan Fratini
出版商	Trans Tech Publications Ltd
页	1031-1040
页数	10
ISBN（电子版）	9783038351931
DOI	https://doi.org/10.4028/www.scientific.net/KEM.622-623.1031
出版状态	已出版 - 2014
活动	15th International Conference on Metal Forming 2014 - Palermo, 意大利期限: 21 9月 2014 → 24 9月 2014

出版系列

姓名	Key Engineering Materials
卷	622-623
ISSN（印刷版）	1013-9826
ISSN（电子版）	1662-9795

会议

会议	15th International Conference on Metal Forming 2014
国家/地区	意大利
市	Palermo
时期	21/09/14 → 24/09/14

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10.4028/www.scientific.net/KEM.622-623.1031

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引用此

Cerreta, E. K., Han, W., Mara, N. A., Beyerlein, I. J., Carpenter, J. S., Zheng, S., Trujillo, C. P., Dickerson, P. O., & Misra, A. (2014). The influence of rolling schedule on the dynamic properties of accumulatively roll bonded nano-layered Cu-Nb. 在 F. Micari, & L. Fratini (编辑), Metal Forming 2014 (页码 1031-1040). (Key Engineering Materials; 卷 622-623). Trans Tech Publications Ltd. https://doi.org/10.4028/www.scientific.net/KEM.622-623.1031

@inproceedings{d0b66999061c453589a967dc836fe78d,

title = "The influence of rolling schedule on the dynamic properties of accumulatively roll bonded nano-layered Cu-Nb",

abstract = "Cu-Nb nano-layered material was produced through an accumulative roll bonding (ARB) technique. Using this technique, two different rolling schedules were employed to produce a normal and transverse rolled material. This resulted in specimens with differing microstructures within the 135nm thick nano-layers and interface structures between the layers. The dynamic response of these bulk Cu-Nb nanocomposites was then investigated under planar shock loading. It was observed in dynamically fractured specimens that the characteristics of ductile failure features formed on the fracture surface after dynamic loading were dependent upon the processing route of the nanocomposite. Specifically, grain shape differences due to dissimilar rolling passes are linked with differences in the failure response, particularly kinetics of fracture. In addition, incipient failure immediately below the primary fracture surface was also observed. Numerous nanovoids were nucleated and aligned linearly in the middle of Cu layers within the shocked Cu-Nb nanocomposites. These observations indicate relative stability of Cu-Nb interfaces produced by the ARB methods utilized in this study under dynamic loading conditions.",

keywords = "Cu-Nb, Damage, Dynamic properties, Nano-laminate, Roll-bonding",

author = "Cerreta, \{Ellen K.\} and Weizhong Han and Mara, \{Nathan A.\} and Beyerlein, \{Irene J.\} and Carpenter, \{John S.\} and Shijian Zheng and Trujillo, \{Carl P.\} and Dickerson, \{Patricia O.\} and Amit Misra",

note = "Publisher Copyright: {\textcopyright} (2014) Trans Tech Publications, Switzerland.; 15th International Conference on Metal Forming 2014 ; Conference date: 21-09-2014 Through 24-09-2014",

year = "2014",

doi = "10.4028/www.scientific.net/KEM.622-623.1031",

language = "英语",

series = "Key Engineering Materials",

publisher = "Trans Tech Publications Ltd",

pages = "1031--1040",

editor = "Fabrizio Micari and Livan Fratini",

booktitle = "Metal Forming 2014",

}

Cerreta, EK, Han, W, Mara, NA, Beyerlein, IJ, Carpenter, JS, Zheng, S, Trujillo, CP, Dickerson, PO & Misra, A 2014, The influence of rolling schedule on the dynamic properties of accumulatively roll bonded nano-layered Cu-Nb. 在 F Micari & L Fratini (编辑), Metal Forming 2014. Key Engineering Materials, 卷 622-623, Trans Tech Publications Ltd, 页码 1031-1040, 15th International Conference on Metal Forming 2014, Palermo, 意大利, 21/09/14. https://doi.org/10.4028/www.scientific.net/KEM.622-623.1031

The influence of rolling schedule on the dynamic properties of accumulatively roll bonded nano-layered Cu-Nb. / Cerreta, Ellen K.; Han, Weizhong; Mara, Nathan A. 等.
Metal Forming 2014. 编辑 / Fabrizio Micari; Livan Fratini. Trans Tech Publications Ltd, 2014. 页码 1031-1040 (Key Engineering Materials; 卷 622-623).

科研成果: 书/报告/会议事项章节 › 会议稿件 › 同行评审

TY - GEN

T1 - The influence of rolling schedule on the dynamic properties of accumulatively roll bonded nano-layered Cu-Nb

AU - Cerreta, Ellen K.

AU - Han, Weizhong

AU - Mara, Nathan A.

AU - Beyerlein, Irene J.

AU - Carpenter, John S.

AU - Zheng, Shijian

AU - Trujillo, Carl P.

AU - Dickerson, Patricia O.

AU - Misra, Amit

N1 - Publisher Copyright: © (2014) Trans Tech Publications, Switzerland.

PY - 2014

Y1 - 2014

N2 - Cu-Nb nano-layered material was produced through an accumulative roll bonding (ARB) technique. Using this technique, two different rolling schedules were employed to produce a normal and transverse rolled material. This resulted in specimens with differing microstructures within the 135nm thick nano-layers and interface structures between the layers. The dynamic response of these bulk Cu-Nb nanocomposites was then investigated under planar shock loading. It was observed in dynamically fractured specimens that the characteristics of ductile failure features formed on the fracture surface after dynamic loading were dependent upon the processing route of the nanocomposite. Specifically, grain shape differences due to dissimilar rolling passes are linked with differences in the failure response, particularly kinetics of fracture. In addition, incipient failure immediately below the primary fracture surface was also observed. Numerous nanovoids were nucleated and aligned linearly in the middle of Cu layers within the shocked Cu-Nb nanocomposites. These observations indicate relative stability of Cu-Nb interfaces produced by the ARB methods utilized in this study under dynamic loading conditions.

AB - Cu-Nb nano-layered material was produced through an accumulative roll bonding (ARB) technique. Using this technique, two different rolling schedules were employed to produce a normal and transverse rolled material. This resulted in specimens with differing microstructures within the 135nm thick nano-layers and interface structures between the layers. The dynamic response of these bulk Cu-Nb nanocomposites was then investigated under planar shock loading. It was observed in dynamically fractured specimens that the characteristics of ductile failure features formed on the fracture surface after dynamic loading were dependent upon the processing route of the nanocomposite. Specifically, grain shape differences due to dissimilar rolling passes are linked with differences in the failure response, particularly kinetics of fracture. In addition, incipient failure immediately below the primary fracture surface was also observed. Numerous nanovoids were nucleated and aligned linearly in the middle of Cu layers within the shocked Cu-Nb nanocomposites. These observations indicate relative stability of Cu-Nb interfaces produced by the ARB methods utilized in this study under dynamic loading conditions.

KW - Cu-Nb

KW - Damage

KW - Dynamic properties

KW - Nano-laminate

KW - Roll-bonding

UR - https://www.scopus.com/pages/publications/84923091876

U2 - 10.4028/www.scientific.net/KEM.622-623.1031

DO - 10.4028/www.scientific.net/KEM.622-623.1031

M3 - 会议稿件

AN - SCOPUS:84923091876

T3 - Key Engineering Materials

SP - 1031

EP - 1040

BT - Metal Forming 2014

A2 - Micari, Fabrizio

A2 - Fratini, Livan

PB - Trans Tech Publications Ltd

T2 - 15th International Conference on Metal Forming 2014

Y2 - 21 September 2014 through 24 September 2014

ER -

The influence of rolling schedule on the dynamic properties of accumulatively roll bonded nano-layered Cu-Nb

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