中国科学院机构知识库网格
Chinese Academy of Sciences Institutional Repositories Grid
High strength and thermal stability of bulk Cu/Ta nanolamellar multilayers fabricated by cross accumulative roll bonding

文献类型:期刊论文

作者Zeng, L. F.1,2; Gao, R.1; Fang, Q. F.1,2; Wang, X. P.1; Xie, Z. M.1,2; Miao, S.1,2; Hao, T.1; Zhang, T.1
刊名ACTA MATERIALIA
出版日期2016-05-15
卷号110期号:页码:341-351
关键词Nanolamellar Multilayers Orientation Relationships High-strength Cross Accumulative Roll Bonding
DOI10.1016/j.actamat.2016.03.034
文献子类Article
英文摘要Bulk Cu/Ta nanolamellar multilayers with an individual layer thickness from several micrometers down to 50 nm were successfully fabricated via a combination of cross accumulative roll bonding (CARB) and an intermediate annealing step. This fabrication technique allowed to effectively suppress the formation of plastic instabilities and edge cracks during the repeated rolling process. A transition of the layered morphology from non-planar interfaces at the submicron level to nearly planar interfaces at the nano scale was observed with decreasing layer thickness. High resolution transmission electron microscopy, selected area electron diffraction and X-ray diffraction were performed, and the results indicate that the Cu/Ta nanolamellar multilayers with a layer thickness of 50 nm show a {100}(Ta)[110]parallel to{110}(Cu)[111] rolling texture relationship. Tensile tests revealed that the ultimate tensile strength of the composite was up to 950 MPa, which is approximately 5 times higher than that of the initial pure Cu and Ta. The hardness of the prepared multilayer maintained unchanged even after an annealing at 500 degrees C for 1 h. These unique properties are attributed to an atomically flat bimetal interface and the low amount of homophase grain boundaries resulted from the CARB process. (C) 2016 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.
WOS关键词SEVERE PLASTIC-DEFORMATION ; ULTRA-HIGH STRENGTH ; NANOLAYERED COMPOSITES ; MECHANICAL-PROPERTIES ; MICROSTRUCTURAL EVOLUTION ; TEXTURE EVOLUTION ; BIMETAL INTERFACES ; DIFFUSION BARRIER ; METAL COMPOSITES ; GRAIN-GROWTH
WOS研究方向Materials Science ; Metallurgy & Metallurgical Engineering
语种英语
WOS记录号WOS:000374810400034
资助机构National Natural Science Foundation of China(11274305 ; National Natural Science Foundation of China(11274305 ; National Natural Science Foundation of China(11274305 ; National Natural Science Foundation of China(11274305 ; National Natural Science Foundation of China(11274305 ; National Natural Science Foundation of China(11274305 ; National Natural Science Foundation of China(11274305 ; National Natural Science Foundation of China(11274305 ; Anhui provincial Natural Science Foundation of China(1408085QE77) ; Anhui provincial Natural Science Foundation of China(1408085QE77) ; Anhui provincial Natural Science Foundation of China(1408085QE77) ; Anhui provincial Natural Science Foundation of China(1408085QE77) ; Anhui provincial Natural Science Foundation of China(1408085QE77) ; Anhui provincial Natural Science Foundation of China(1408085QE77) ; Anhui provincial Natural Science Foundation of China(1408085QE77) ; Anhui provincial Natural Science Foundation of China(1408085QE77) ; 11374299 ; 11374299 ; 11374299 ; 11374299 ; 11374299 ; 11374299 ; 11374299 ; 11374299 ; 11475216) ; 11475216) ; 11475216) ; 11475216) ; 11475216) ; 11475216) ; 11475216) ; 11475216) ; National Natural Science Foundation of China(11274305 ; National Natural Science Foundation of China(11274305 ; National Natural Science Foundation of China(11274305 ; National Natural Science Foundation of China(11274305 ; National Natural Science Foundation of China(11274305 ; National Natural Science Foundation of China(11274305 ; National Natural Science Foundation of China(11274305 ; National Natural Science Foundation of China(11274305 ; Anhui provincial Natural Science Foundation of China(1408085QE77) ; Anhui provincial Natural Science Foundation of China(1408085QE77) ; Anhui provincial Natural Science Foundation of China(1408085QE77) ; Anhui provincial Natural Science Foundation of China(1408085QE77) ; Anhui provincial Natural Science Foundation of China(1408085QE77) ; Anhui provincial Natural Science Foundation of China(1408085QE77) ; Anhui provincial Natural Science Foundation of China(1408085QE77) ; Anhui provincial Natural Science Foundation of China(1408085QE77) ; 11374299 ; 11374299 ; 11374299 ; 11374299 ; 11374299 ; 11374299 ; 11374299 ; 11374299 ; 11475216) ; 11475216) ; 11475216) ; 11475216) ; 11475216) ; 11475216) ; 11475216) ; 11475216)
源URL[http://ir.hfcas.ac.cn:8080/handle/334002/22091]  
专题合肥物质科学研究院_中科院固体物理研究所
作者单位1.Chinese Acad Sci, Inst Solid State Phys, Key Lab Mat Phys, Hefei 230031, Peoples R China
2.Univ Sci & Technol China, Hefei 230026, Peoples R China
推荐引用方式
GB/T 7714
Zeng, L. F.,Gao, R.,Fang, Q. F.,et al. High strength and thermal stability of bulk Cu/Ta nanolamellar multilayers fabricated by cross accumulative roll bonding[J]. ACTA MATERIALIA,2016,110(无):341-351.
APA Zeng, L. F..,Gao, R..,Fang, Q. F..,Wang, X. P..,Xie, Z. M..,...&Zhang, T..(2016).High strength and thermal stability of bulk Cu/Ta nanolamellar multilayers fabricated by cross accumulative roll bonding.ACTA MATERIALIA,110(无),341-351.
MLA Zeng, L. F.,et al."High strength and thermal stability of bulk Cu/Ta nanolamellar multilayers fabricated by cross accumulative roll bonding".ACTA MATERIALIA 110.无(2016):341-351.

入库方式: OAI收割

来源:合肥物质科学研究院

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