Shear-band-to-crack transition in bulk metallic glasses under quasi-static and dynamic shearing

The intrinsic fracture mechanism of bulk metallic glasses (BMGs) is often obscured with the involvement of normal stress. To decouple the normal-stress effect, a double-notched shearing technique is developed to investigate the mechanical properties of BMGs. Real-time shear banding and fracture beha...

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Bibliographic Details
Published in:Journal of non-crystalline solids 2019-10, Vol.521, p.119484, Article 119484
Main Authors: Zhou, Ding, Zhao, Xianhang, Li, Bingjin, Hou, Naidan, Ma, Zihao, Sun, Tianfu, Hou, Bing, Li, Yulong
Format: Article
Language:English
Subjects:
Cavitation concentration
Cavitation instabilities
Double-notched shearing
High-speed photographing
Transition
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Summary:The intrinsic fracture mechanism of bulk metallic glasses (BMGs) is often obscured with the involvement of normal stress. To decouple the normal-stress effect, a double-notched shearing technique is developed to investigate the mechanical properties of BMGs. Real-time shear banding and fracture behavior under quasi-static and dynamic shearing are captured by using high-speed photographing, which confirms multiple shear banding at low strain rates and single shear banding at high strain rates. More importantly, the transition from shear band to crack could be observed with little influence of normal stress. Such transition is found to be induced by cavitation mechanism and shows obvious rate dependence; that is originated from regularly distributed controllable cavities under quasi-static loading, while from a series of concentrated cavitation under dynamic loading. Referring to studies under compression and tension, we clarify that strain rate controls cavitation concentration level and normal stress controls cavitation instabilities, respectively. •A double-shear technique is developed under quasi-static and dynamic shearing.•Real-time shear banding and fracture behavior are captured.•Shear-band-to-crack transition is due to rate-dependent cavity-based mechanisms.•Strain rate controls cavitation concentration level.•Normal stress controls cavitation instabilities.
ISSN:0022-3093
1873-4812
DOI:10.1016/j.jnoncrysol.2019.119484