Oxidation-induced superelasticity in metallic glass nanotubes

Fucheng Li; Zhibo Zhang; Huanrong Liu; Wenqing Zhu; Tianyu Wang; Minhyuk Park; Jingyang Zhang; Niklas Bönninghoff; Xiaobin Feng; Hongti Zhang; Junhua Luan; Jianguo Wang; Xiaodi Liu; Tinghao Chang; Jinn P. Chu; Yang Lu; Yanhui Liu; Pengfei Guan; Yong Yang

doi:10.1038/s41563-023-01733-8

Oxidation-induced superelasticity in metallic glass nanotubes

Fucheng Li (Co-first Author), Zhibo Zhang (Co-first Author), Huanrong Liu (Co-first Author), Wenqing Zhu, Tianyu Wang, Minhyuk Park, Jingyang Zhang, Niklas Bönninghoff, Xiaobin Feng, Hongti Zhang, Junhua Luan, Jianguo Wang, Xiaodi Liu, Tinghao Chang, Jinn P. Chu, Yang Lu, Yanhui Liu^*, Pengfei Guan^*, Yong Yang^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

25 Citations (Scopus)

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Abstract

Although metallic nanostructures have been attracting tremendous research interest in nanoscience and nanotechnologies, it is known that environmental attacks, such as surface oxidation, can easily initiate cracking on the surface of metals, thus deteriorating their overall functional/structural properties. In sharp contrast, here we report that severely oxidized metallic glass nanotubes can attain an ultrahigh recoverable elastic strain of up to ~14% at room temperature, which outperform bulk metallic glasses, metallic glass nanowires and many other superelastic metals hitherto reported. Through in situ experiments and atomistic simulations, we reveal that the physical mechanisms underpinning the observed superelasticity can be attributed to the formation of a percolating oxide network in metallic glass nanotubes, which not only restricts atomic-scale plastic events during loading but also leads to the recovery of elastic rigidity on unloading. Our discovery implies that oxidation in low-dimensional metallic glasses can result in unique properties for applications in nanodevices. © 2023, The Author(s), under exclusive licence to Springer Nature Limited.

Original language	English
Pages (from-to)	52-57
Journal	Nature Materials
Volume	23
Online published	5 Dec 2023
DOIs	https://doi.org/10.1038/s41563-023-01733-8
Publication status	Published - Jan 2024

Funding

The research of YY is supported by the research grant council (RGC), the Hong Kong government, through the general research fund (GRF) with the grant numbers of N_CityU 109/21, CityU11200719 and CityU11213118. P.F.G acknowledges support 23 from the NSF of China (Grant Nos. 5211101002, and U1930402). We acknowledge the computational support from the Beijing Computational Science Research Center (CSRC). Y.H. L acknowledges support from the National Natural Science Foundation of China (Grant no. 51825104). L.F.C acknowledges support from the China Postdoctoral Science Foundation (Grant Nos. 2020TQ0346), Guangdong Major Project of Basic and Applied Basic Research, China (Grant No. 2019B030302010) and the National Natural Science Foundation of China (Grant no. 52201195). Y.L acknowledges the support from RGC under RFS2021-1S05. J.G.W acknowledges support from the NSF of China (Grant Nos. 52071081).

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COPYRIGHT TERMS OF DEPOSITED POSTPRINT FILE: This version of the article has been accepted for publication, after peer review (when applicable) and is subject to Springer Nature’s AM terms of use, but is not the Version of Record and does not reflect post-acceptance improvements, or any corrections. The Version of Record is available online at: https://doi.org/10.1038/s41563-023-01733-8.

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abstract = "Although metallic nanostructures have been attracting tremendous research interest in nanoscience and nanotechnologies, it is known that environmental attacks, such as surface oxidation, can easily initiate cracking on the surface of metals, thus deteriorating their overall functional/structural properties. In sharp contrast, here we report that severely oxidized metallic glass nanotubes can attain an ultrahigh recoverable elastic strain of up to ~14% at room temperature, which outperform bulk metallic glasses, metallic glass nanowires and many other superelastic metals hitherto reported. Through in situ experiments and atomistic simulations, we reveal that the physical mechanisms underpinning the observed superelasticity can be attributed to the formation of a percolating oxide network in metallic glass nanotubes, which not only restricts atomic-scale plastic events during loading but also leads to the recovery of elastic rigidity on unloading. Our discovery implies that oxidation in low-dimensional metallic glasses can result in unique properties for applications in nanodevices. {\textcopyright} 2023, The Author(s), under exclusive licence to Springer Nature Limited.",

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AU - Zhang, Zhibo

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AU - Park, Minhyuk

AU - Zhang, Jingyang

AU - Bönninghoff, Niklas

AU - Feng, Xiaobin

AU - Zhang, Hongti

AU - Luan, Junhua

AU - Wang, Jianguo

AU - Liu, Xiaodi

AU - Chang, Tinghao

AU - Chu, Jinn P.

AU - Lu, Yang

AU - Liu, Yanhui

AU - Guan, Pengfei

AU - Yang, Yong

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ER -

Oxidation-induced superelasticity in metallic glass nanotubes

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NSFC: Two-Dimensional (2D) Metallic Glasses: From Synthesis, Physical/Mechanical Properties to Alloy Design

GRF: Development of Strong-yet-Ductile Nanograined Alloys with Intergranular Amorphous Films Based on Metallic-Glass Templates

GRF: The Development of Dual-Phase Fe-Based Metallic Glasses and Composites with Optimized Mechanical and Magnetic Properties

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Oxidation-induced superelasticity in metallic glass nanotubes

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NSFC: Two-Dimensional (2D) Metallic Glasses: From Synthesis, Physical/Mechanical Properties to Alloy Design

GRF: Development of Strong-yet-Ductile Nanograined Alloys with Intergranular Amorphous Films Based on Metallic-Glass Templates

GRF: The Development of Dual-Phase Fe-Based Metallic Glasses and Composites with Optimized Mechanical and Magnetic Properties

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