Observation of speeding growth of metal nanowires by ultra-low frequency micro-vibration assisted superplastic nanomolding

•The molding efficiency is drastically increased by superimposing micro-vibration.•Vibration with ultra-low frequency (~1 Hz) has ultra-strong effects on nanomolding.•The observations deepen the understanding of the metal deformation mechanism. Superplastic nanomolding (SPNM), a method to directly f...

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Bibliographic Details
Published inMaterials letters Vol. 283; p. 128890
Main Authors Zhang, Yujie, Wu, Bozhao, Gao, Enlai, Shui, Langquan, Liu, Ze
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 15.01.2021
Elsevier BV
Subjects
Deformation
Extremely low frequencies
Friction reduction
Materials science
Metal forming and shaping
Metal nanowires
Metal surfaces
Molds
Nanostructure
Nanowires
Superplastic nanomolding
Superplasticity
Surfaces
Ultra-low frequency micro-vibration
Vibration
Surfaces
Superplastic nanomolding
Metal forming and shaping
Metal nanowires
Ultra-low frequency micro-vibration
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Summary:•The molding efficiency is drastically increased by superimposing micro-vibration.•Vibration with ultra-low frequency (~1 Hz) has ultra-strong effects on nanomolding.•The observations deepen the understanding of the metal deformation mechanism. Superplastic nanomolding (SPNM), a method to directly form nanostructures in metal surface through contact deformation by using a hard mold, provides a toolbox to mold essentially any metals on the nanoscale. Here, by superimposing an ultra-low frequency micro-vibration to the molding pressure, it is interesting to find that the molding efficiency can be drastically increased. Specifically, the length of molded Ag nanowires increased by 20% when a micro-vibration (with a frequency as low as 100 Hz) is exerted. The speeding growth of the Ag nanowires during SPNM is attributed to the interfacial friction reduction and material softening induced by vibration according to the experimental results. Based on the thermal activation theory, a theoretical model is developed, which predicts that the micro-vibration accelerated deformation increases as the vibration frequency, agreeing with experiments well. These findings are expected to facilitate the wide application of SPNM in the quick fabrication of metal nanostructures.
ISSN:0167-577X
1873-4979
DOI:10.1016/j.matlet.2020.128890