Interface characteristics of a Zr-based BMG/copper laminated composite

L. L. Sun; J. Wang; H. C. Kou; B. Tang; J. S. Li; P. X. Zhang

doi:10.1002/sia.5346

Interface characteristics of a Zr-based BMG/copper laminated composite

L. L. Sun, J. Wang, H. C. Kou, B. Tang, J. S. Li, P. X. Zhang

School of Materials Sience and Engineering

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

9 Scopus citations

Abstract

Diffusion bonding of metallic glasses and crystalline metals utilizing excellent superplasticity of monolithic bulk metallic glasses (BMGs) within supercooled liquid region has been found to be an efficient method to improve the room temperature plasticity and fracture toughness of metallic glass. A Zr-based BMG/copper laminated composite was fabricated by copressing method, and the interface bonding status was characterized by scanning electron microscopy (SEM) and high-resolution transmission electron microscopy. No void or crack is detected, and the interface is a metallurgical bonding of atomistic level. Although the BMG retains amorphous state after copressing at 390 °C, the region of the amorphous-crystalline mixture structure with the width of 30-40 nm occurred within the diffusion zone.

Original language	English
Pages (from-to)	61-64
Number of pages	4
Journal	Surface and Interface Analysis
Volume	46
Issue number	2
DOIs	https://doi.org/10.1002/sia.5346
State	Published - Feb 2014

Keywords

interface
laminated composite
metallic glass
nano-crystal

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abstract = "Diffusion bonding of metallic glasses and crystalline metals utilizing excellent superplasticity of monolithic bulk metallic glasses (BMGs) within supercooled liquid region has been found to be an efficient method to improve the room temperature plasticity and fracture toughness of metallic glass. A Zr-based BMG/copper laminated composite was fabricated by copressing method, and the interface bonding status was characterized by scanning electron microscopy (SEM) and high-resolution transmission electron microscopy. No void or crack is detected, and the interface is a metallurgical bonding of atomistic level. Although the BMG retains amorphous state after copressing at 390 °C, the region of the amorphous-crystalline mixture structure with the width of 30-40 nm occurred within the diffusion zone.",

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AU - Sun, L. L.

AU - Wang, J.

AU - Kou, H. C.

AU - Tang, B.

AU - Li, J. S.

AU - Zhang, P. X.

PY - 2014/2

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AB - Diffusion bonding of metallic glasses and crystalline metals utilizing excellent superplasticity of monolithic bulk metallic glasses (BMGs) within supercooled liquid region has been found to be an efficient method to improve the room temperature plasticity and fracture toughness of metallic glass. A Zr-based BMG/copper laminated composite was fabricated by copressing method, and the interface bonding status was characterized by scanning electron microscopy (SEM) and high-resolution transmission electron microscopy. No void or crack is detected, and the interface is a metallurgical bonding of atomistic level. Although the BMG retains amorphous state after copressing at 390 °C, the region of the amorphous-crystalline mixture structure with the width of 30-40 nm occurred within the diffusion zone.

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Interface characteristics of a Zr-based BMG/copper laminated composite

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