Tailoring plasticity of metallic glasses via interfaces in Cu/amorphous CuNb laminates

Zhe Fan; Qiang Li; Jin Li; Sichuang Xue; Haiyan Wang; Xinghang Zhang

doi:10.1557/jmr.2017.249

Tailoring plasticity of metallic glasses via interfaces in Cu/amorphous CuNb laminates

Zhe Fan
, Qiang Li
, Jin Li
, Sichuang Xue
, Haiyan Wang
, Xinghang Zhang

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

22 Scopus citations

Abstract

Metallic glasses (MGs) are known to have high strength, but poor ductility. Prior studies have shown that plasticity in MG can be enhanced by significantly reducing their dimension to nanoscale. Here we show that, via the introduction of certain types of crystalline/amorphous interfaces, plasticity of MG can be prominently enhanced as manifested by the formation of ductile dimples in a 2 μm thick amorphous CuNb film. By tailoring the volume fraction and architecture of crystalline/amorphous multilayers, tensile fracture surface of MG can evolve from brittle featureless morphology to containing ductile dimples. In situ micropillar compression studies performed inside a scanning electron microscope show that shear instability in amorphous layers can be inhibited by interfaces. The mechanisms for improving plasticity and fracture resistance of MG via interface and size effect are discussed.

Original language	English
Pages (from-to)	2680-2689
Number of pages	10
Journal	Journal of Materials Research
Volume	32
Issue number	14
DOIs	https://doi.org/10.1557/jmr.2017.249
State	Published - 28 Jul 2017
Externally published	Yes

Keywords

amorphous
crystalline
thin film

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10.1557/jmr.2017.249

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title = "Tailoring plasticity of metallic glasses via interfaces in Cu/amorphous CuNb laminates",

abstract = "Metallic glasses (MGs) are known to have high strength, but poor ductility. Prior studies have shown that plasticity in MG can be enhanced by significantly reducing their dimension to nanoscale. Here we show that, via the introduction of certain types of crystalline/amorphous interfaces, plasticity of MG can be prominently enhanced as manifested by the formation of ductile dimples in a 2 μm thick amorphous CuNb film. By tailoring the volume fraction and architecture of crystalline/amorphous multilayers, tensile fracture surface of MG can evolve from brittle featureless morphology to containing ductile dimples. In situ micropillar compression studies performed inside a scanning electron microscope show that shear instability in amorphous layers can be inhibited by interfaces. The mechanisms for improving plasticity and fracture resistance of MG via interface and size effect are discussed.",

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author = "Zhe Fan and Qiang Li and Jin Li and Sichuang Xue and Haiyan Wang and Xinghang Zhang",

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doi = "10.1557/jmr.2017.249",

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T1 - Tailoring plasticity of metallic glasses via interfaces in Cu/amorphous CuNb laminates

AU - Fan, Zhe

AU - Li, Qiang

AU - Li, Jin

AU - Xue, Sichuang

AU - Wang, Haiyan

AU - Zhang, Xinghang

PY - 2017/7/28

Y1 - 2017/7/28

N2 - Metallic glasses (MGs) are known to have high strength, but poor ductility. Prior studies have shown that plasticity in MG can be enhanced by significantly reducing their dimension to nanoscale. Here we show that, via the introduction of certain types of crystalline/amorphous interfaces, plasticity of MG can be prominently enhanced as manifested by the formation of ductile dimples in a 2 μm thick amorphous CuNb film. By tailoring the volume fraction and architecture of crystalline/amorphous multilayers, tensile fracture surface of MG can evolve from brittle featureless morphology to containing ductile dimples. In situ micropillar compression studies performed inside a scanning electron microscope show that shear instability in amorphous layers can be inhibited by interfaces. The mechanisms for improving plasticity and fracture resistance of MG via interface and size effect are discussed.

AB - Metallic glasses (MGs) are known to have high strength, but poor ductility. Prior studies have shown that plasticity in MG can be enhanced by significantly reducing their dimension to nanoscale. Here we show that, via the introduction of certain types of crystalline/amorphous interfaces, plasticity of MG can be prominently enhanced as manifested by the formation of ductile dimples in a 2 μm thick amorphous CuNb film. By tailoring the volume fraction and architecture of crystalline/amorphous multilayers, tensile fracture surface of MG can evolve from brittle featureless morphology to containing ductile dimples. In situ micropillar compression studies performed inside a scanning electron microscope show that shear instability in amorphous layers can be inhibited by interfaces. The mechanisms for improving plasticity and fracture resistance of MG via interface and size effect are discussed.

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KW - crystalline

KW - thin film

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DO - 10.1557/jmr.2017.249

M3 - 文章

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EP - 2689

JO - Journal of Materials Research

JF - Journal of Materials Research

IS - 14

ER -

Tailoring plasticity of metallic glasses via interfaces in Cu/amorphous CuNb laminates

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Keywords

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