Oxide-Metal Hybrid Glass Nanomembranes with Exceptional Thermal Stability

Ziyin Yang; Shan Zhang; Zhibo Zhang; Huanrong Liu; Yun Teng; Hang Wang; Hao Gong; Yinghui Shang; Baisong Guo; Yue Fan; Haibo Ke; Weihua Wang; Pengfei Guan; Yong Yang

doi:10.1021/acs.nanolett.4c04555

Oxide-Metal Hybrid Glass Nanomembranes with Exceptional Thermal Stability

Ziyin Yang, Shan Zhang, Zhibo Zhang, Huanrong Liu, Yun Teng, Hang Wang, Hao Gong, Yinghui Shang, Baisong Guo, Yue Fan, Haibo Ke^*, Weihua Wang^*, Pengfei Guan^*, Yong Yang^*

^*Corresponding author for this work

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

Abstract

Contrary to oxide or polymeric glasses, metallic glasses are infamously known for their relatively limited thermal stability, which is often characterized by their narrow supercooled liquid regions. Nonetheless, we successfully fabricated metallic-glass based nanomembranes with an ultrahigh thermal ability by a polymer surface buckling enabled exfoliation technique. These nanomembranes exhibit a distinctive nanostructure with nanosized metallic-glasses encapsulated within an interconnected nanoamorphous-oxide network. Due to a pronounced nanoconfinement effect, crystallization is significantly suppressed. Consequently, these oxidized metallic-glass nanomembranes initiate a glass transition at 324 K at a heating rate of 10 K/min. Remarkably, they also showcase an expansive supercooled liquid region of 448 K, surpassing various metallic and oxide glasses reported. Furthermore, these nanomembranes not only exhibit a low elastic modulus but also achieve superplasticity even at room temperature. This unique blend of thermomechanical properties positions our metallic-glass based nanomembranes as an ideal candidate for nanofabrication processing, such as nanoimprinting, for the creation of next-generation nanodevices. © 2024 American Chemical Society.

Original language	English
Pages (from-to)	14475–14483
Journal	Nano Letters
Volume	24
Issue number	45
Online published	30 Oct 2024
DOIs	https://doi.org/10.1021/acs.nanolett.4c04555
Publication status	Published - 13 Nov 2024

Funding

H.B.K. acknowledges the support of Guangdong Major Project of Basic and Applied Basic Research, China (Grant No. 2019B030302010), the National Natural Science Foundation of China (Grant Nos. 52071222), the National Key Research and Development Program of China (Grant No. 2021YFA0716302). Y.Y. gratefully acknowledges the support of Research Grants Council (RGC), Hong Kong government, through the General Research Fund (GRF) with the grant number of CityU 11206362 and through the NSFC-RGC joint research scheme with the grant number of N_CityU 109/21. P.F.G acknowledges the support of National Natural Science Foundation of China (T2325004 and 52161160330). B.S.G acknowledges the support of National Natural Science Foundation of China (52271132); Guangzhou Science and Technology Planning Project (2024A04J9966); Guangdong Provincial Science and Technology Plan Project (2022A0505050043).

Research Keywords

glass transition
heterogeneity
metallic glass
nanoconfinement
thermal stability

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title = "Oxide-Metal Hybrid Glass Nanomembranes with Exceptional Thermal Stability",

abstract = "Contrary to oxide or polymeric glasses, metallic glasses are infamously known for their relatively limited thermal stability, which is often characterized by their narrow supercooled liquid regions. Nonetheless, we successfully fabricated metallic-glass based nanomembranes with an ultrahigh thermal ability by a polymer surface buckling enabled exfoliation technique. These nanomembranes exhibit a distinctive nanostructure with nanosized metallic-glasses encapsulated within an interconnected nanoamorphous-oxide network. Due to a pronounced nanoconfinement effect, crystallization is significantly suppressed. Consequently, these oxidized metallic-glass nanomembranes initiate a glass transition at 324 K at a heating rate of 10 K/min. Remarkably, they also showcase an expansive supercooled liquid region of 448 K, surpassing various metallic and oxide glasses reported. Furthermore, these nanomembranes not only exhibit a low elastic modulus but also achieve superplasticity even at room temperature. This unique blend of thermomechanical properties positions our metallic-glass based nanomembranes as an ideal candidate for nanofabrication processing, such as nanoimprinting, for the creation of next-generation nanodevices. {\textcopyright} 2024 American Chemical Society.",

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author = "Ziyin Yang and Shan Zhang and Zhibo Zhang and Huanrong Liu and Yun Teng and Hang Wang and Hao Gong and Yinghui Shang and Baisong Guo and Yue Fan and Haibo Ke and Weihua Wang and Pengfei Guan and Yong Yang",

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TY - JOUR

T1 - Oxide-Metal Hybrid Glass Nanomembranes with Exceptional Thermal Stability

AU - Yang, Ziyin

AU - Zhang, Shan

AU - Zhang, Zhibo

AU - Liu, Huanrong

AU - Teng, Yun

AU - Wang, Hang

AU - Gong, Hao

AU - Shang, Yinghui

AU - Guo, Baisong

AU - Fan, Yue

AU - Ke, Haibo

AU - Wang, Weihua

AU - Guan, Pengfei

AU - Yang, Yong

PY - 2024/11/13

Y1 - 2024/11/13

N2 - Contrary to oxide or polymeric glasses, metallic glasses are infamously known for their relatively limited thermal stability, which is often characterized by their narrow supercooled liquid regions. Nonetheless, we successfully fabricated metallic-glass based nanomembranes with an ultrahigh thermal ability by a polymer surface buckling enabled exfoliation technique. These nanomembranes exhibit a distinctive nanostructure with nanosized metallic-glasses encapsulated within an interconnected nanoamorphous-oxide network. Due to a pronounced nanoconfinement effect, crystallization is significantly suppressed. Consequently, these oxidized metallic-glass nanomembranes initiate a glass transition at 324 K at a heating rate of 10 K/min. Remarkably, they also showcase an expansive supercooled liquid region of 448 K, surpassing various metallic and oxide glasses reported. Furthermore, these nanomembranes not only exhibit a low elastic modulus but also achieve superplasticity even at room temperature. This unique blend of thermomechanical properties positions our metallic-glass based nanomembranes as an ideal candidate for nanofabrication processing, such as nanoimprinting, for the creation of next-generation nanodevices. © 2024 American Chemical Society.

AB - Contrary to oxide or polymeric glasses, metallic glasses are infamously known for their relatively limited thermal stability, which is often characterized by their narrow supercooled liquid regions. Nonetheless, we successfully fabricated metallic-glass based nanomembranes with an ultrahigh thermal ability by a polymer surface buckling enabled exfoliation technique. These nanomembranes exhibit a distinctive nanostructure with nanosized metallic-glasses encapsulated within an interconnected nanoamorphous-oxide network. Due to a pronounced nanoconfinement effect, crystallization is significantly suppressed. Consequently, these oxidized metallic-glass nanomembranes initiate a glass transition at 324 K at a heating rate of 10 K/min. Remarkably, they also showcase an expansive supercooled liquid region of 448 K, surpassing various metallic and oxide glasses reported. Furthermore, these nanomembranes not only exhibit a low elastic modulus but also achieve superplasticity even at room temperature. This unique blend of thermomechanical properties positions our metallic-glass based nanomembranes as an ideal candidate for nanofabrication processing, such as nanoimprinting, for the creation of next-generation nanodevices. © 2024 American Chemical Society.

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KW - heterogeneity

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DO - 10.1021/acs.nanolett.4c04555

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JO - Nano Letters

JF - Nano Letters

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ER -

Oxide-Metal Hybrid Glass Nanomembranes with Exceptional Thermal Stability

Abstract

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Research Keywords

UN SDGs

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

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Oxide-Metal Hybrid Glass Nanomembranes with Exceptional Thermal Stability

Abstract

Funding

Research Keywords

UN SDGs

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Other Access Options

Permanent Link

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

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