Single-crystal two-dimensional material epitaxy on tailored non-single-crystal substrates

Xin Li; Guilin Wu; Leining Zhang; Deping Huang; Yunqing Li; Ruiqi Zhang; Meng Li; Lin Zhu; Jing Guo; Tianlin Huang; Jun Shen; Xingzhan Wei; Ka Man Yu; Jichen Dong; Michael S. Altman; Rodney S. Ruoff; Yinwu Duan; Jie Yu; Zhujun Wang; Xiaoxu Huang; Feng Ding; Haofei Shi; Wenxin Tang

doi:10.1038/s41467-022-29451-w

Single-crystal two-dimensional material epitaxy on tailored non-single-crystal substrates

Xin Li, Guilin Wu, Leining Zhang, Deping Huang, Yunqing Li, Ruiqi Zhang, Meng Li, Lin Zhu, Jing Guo, Tianlin Huang, Jun Shen, Xingzhan Wei, Ka Man Yu, Jichen Dong, Michael S. Altman, Rodney S. Ruoff, Yinwu Duan, Jie Yu, Zhujun Wang, Xiaoxu Huang^*Feng Ding^*, Haofei Shi^*, Wenxin Tang

^*此作品的通讯作者

科研成果: 期刊稿件 › 文章 › 同行评审

20 引用（Scopus）

摘要

The use of single-crystal substrates as templates for the epitaxial growth of single-crystal overlayers has been a primary principle of materials epitaxy for more than 70 years. Here we report our finding that, though counterintuitive, single-crystal 2D materials can be epitaxially grown on twinned crystals. By establishing a geometric principle to describe 2D materials alignment on high-index surfaces, we show that 2D material islands grown on the two sides of a twin boundary can be well aligned. To validate this prediction, wafer-scale Cu foils with abundant twin boundaries were synthesized, and on the surfaces of these polycrystalline Cu foils, we have successfully grown wafer-scale single-crystal graphene and hexagonal boron nitride films. In addition, to greatly increasing the availability of large area high-quality 2D single crystals, our discovery also extends the fundamental understanding of materials epitaxy.

源语言	英语
文章编号	1773
期刊	Nature Communications
卷	13
期	1
DOI	https://doi.org/10.1038/s41467-022-29451-w
出版状态	已出版 - 12月 2022
已对外发布	是

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Li, X., Wu, G., Zhang, L., Huang, D., Li, Y., Zhang, R., Li, M., Zhu, L., Guo, J., Huang, T., Shen, J., Wei, X., Yu, K. M., Dong, J., Altman, M. S., Ruoff, R. S., Duan, Y., Yu, J., Wang, Z., ... Tang, W. (2022). Single-crystal two-dimensional material epitaxy on tailored non-single-crystal substrates. Nature Communications, 13(1), 文章 1773. https://doi.org/10.1038/s41467-022-29451-w

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title = "Single-crystal two-dimensional material epitaxy on tailored non-single-crystal substrates",

abstract = "The use of single-crystal substrates as templates for the epitaxial growth of single-crystal overlayers has been a primary principle of materials epitaxy for more than 70 years. Here we report our finding that, though counterintuitive, single-crystal 2D materials can be epitaxially grown on twinned crystals. By establishing a geometric principle to describe 2D materials alignment on high-index surfaces, we show that 2D material islands grown on the two sides of a twin boundary can be well aligned. To validate this prediction, wafer-scale Cu foils with abundant twin boundaries were synthesized, and on the surfaces of these polycrystalline Cu foils, we have successfully grown wafer-scale single-crystal graphene and hexagonal boron nitride films. In addition, to greatly increasing the availability of large area high-quality 2D single crystals, our discovery also extends the fundamental understanding of materials epitaxy.",

author = "Xin Li and Guilin Wu and Leining Zhang and Deping Huang and Yunqing Li and Ruiqi Zhang and Meng Li and Lin Zhu and Jing Guo and Tianlin Huang and Jun Shen and Xingzhan Wei and Yu, {Ka Man} and Jichen Dong and Altman, {Michael S.} and Ruoff, {Rodney S.} and Yinwu Duan and Jie Yu and Zhujun Wang and Xiaoxu Huang and Feng Ding and Haofei Shi and Wenxin Tang",

note = "Publisher Copyright: {\textcopyright} 2022, The Author(s).",

year = "2022",

month = dec,

doi = "10.1038/s41467-022-29451-w",

language = "English",

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Li, X, Wu, G, Zhang, L, Huang, D, Li, Y, Zhang, R, Li, M, Zhu, L, Guo, J, Huang, T, Shen, J, Wei, X, Yu, KM, Dong, J, Altman, MS, Ruoff, RS, Duan, Y, Yu, J, Wang, Z, Huang, X, Ding, F, Shi, H & Tang, W 2022, 'Single-crystal two-dimensional material epitaxy on tailored non-single-crystal substrates', Nature Communications, 卷 13, 号码 1, 1773. https://doi.org/10.1038/s41467-022-29451-w

TY - JOUR

T1 - Single-crystal two-dimensional material epitaxy on tailored non-single-crystal substrates

AU - Li, Xin

AU - Wu, Guilin

AU - Zhang, Leining

AU - Huang, Deping

AU - Li, Yunqing

AU - Zhang, Ruiqi

AU - Li, Meng

AU - Zhu, Lin

AU - Guo, Jing

AU - Huang, Tianlin

AU - Shen, Jun

AU - Wei, Xingzhan

AU - Yu, Ka Man

AU - Dong, Jichen

AU - Altman, Michael S.

AU - Ruoff, Rodney S.

AU - Duan, Yinwu

AU - Yu, Jie

AU - Wang, Zhujun

AU - Huang, Xiaoxu

AU - Ding, Feng

AU - Shi, Haofei

AU - Tang, Wenxin

PY - 2022/12

Y1 - 2022/12

N2 - The use of single-crystal substrates as templates for the epitaxial growth of single-crystal overlayers has been a primary principle of materials epitaxy for more than 70 years. Here we report our finding that, though counterintuitive, single-crystal 2D materials can be epitaxially grown on twinned crystals. By establishing a geometric principle to describe 2D materials alignment on high-index surfaces, we show that 2D material islands grown on the two sides of a twin boundary can be well aligned. To validate this prediction, wafer-scale Cu foils with abundant twin boundaries were synthesized, and on the surfaces of these polycrystalline Cu foils, we have successfully grown wafer-scale single-crystal graphene and hexagonal boron nitride films. In addition, to greatly increasing the availability of large area high-quality 2D single crystals, our discovery also extends the fundamental understanding of materials epitaxy.

AB - The use of single-crystal substrates as templates for the epitaxial growth of single-crystal overlayers has been a primary principle of materials epitaxy for more than 70 years. Here we report our finding that, though counterintuitive, single-crystal 2D materials can be epitaxially grown on twinned crystals. By establishing a geometric principle to describe 2D materials alignment on high-index surfaces, we show that 2D material islands grown on the two sides of a twin boundary can be well aligned. To validate this prediction, wafer-scale Cu foils with abundant twin boundaries were synthesized, and on the surfaces of these polycrystalline Cu foils, we have successfully grown wafer-scale single-crystal graphene and hexagonal boron nitride films. In addition, to greatly increasing the availability of large area high-quality 2D single crystals, our discovery also extends the fundamental understanding of materials epitaxy.

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Single-crystal two-dimensional material epitaxy on tailored non-single-crystal substrates

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