Toward a mechanistic understanding of vertical growth of van der Waals stacked 2D materials : a multiscale model and experiments
Vertical stacking of monolayers via van der Waals (vdW) interaction opens promising routes toward engineering physical properties of two-dimensional (2D) materials and designing atomically thin devices. However, due to the lack of mechanistic understanding, challenges remain in the controlled fabric...
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sg-ntu-dr.10356-1414652020-06-08T09:17:10Z Toward a mechanistic understanding of vertical growth of van der Waals stacked 2D materials : a multiscale model and experiments Ye, Han Zhou, Jiadong Er, Dequan Price, Christopher C. Yu, Zhongyuan Liu, Yumin Lowengrub, John Lou, Jun Liu, Zheng Shenoy, Vivek B. School of Materials Science and Engineering Centre for Programmable Materials Engineering::Materials Vertically Stacked 2D Materials Growth Mechanisms Vertical stacking of monolayers via van der Waals (vdW) interaction opens promising routes toward engineering physical properties of two-dimensional (2D) materials and designing atomically thin devices. However, due to the lack of mechanistic understanding, challenges remain in the controlled fabrication of these structures via scalable methods such as chemical vapor deposition (CVD) onto substrates. In this paper, we develop a general multiscale model to describe the size evolution of 2D layers and predict the necessary growth conditions for vertical (initial + subsequent layers) versus in-plane lateral (monolayer) growth. An analytic thermodynamic criterion is established for subsequent layer growth that depends on the sizes of both layers, the vdW interaction energies, and the edge energy of 2D layers. Considering the time-dependent growth process, we find that temperature and adatom flux from vapor are the primary criteria affecting the self-assembled growth. The proposed model clearly demonstrates the distinct roles of thermodynamic and kinetic mechanisms governing the final structure. Our model agrees with experimental observations of various monolayer and bilayer transition metal dichalcogenides grown by CVD and provides a predictive framework to guide the fabrication of vertically stacked 2D materials. NRF (Natl Research Foundation, S’pore) MOE (Min. of Education, S’pore) 2020-06-08T09:17:09Z 2020-06-08T09:17:09Z 2017 Journal Article Ye, H., Zhou, J., Er, D., Price, C. C., Yu, Z., Liu, Y., . . . Shenoy, V. B. (2017). Toward a mechanistic understanding of vertical growth of van der Waals stacked 2D materials : a multiscale model and experiments. ACS Nano, 11(12), 12780-12788. doi:10.1021/acsnano.7b07604 1936-0851 https://hdl.handle.net/10356/141465 10.1021/acsnano.7b07604 29206441 2-s2.0-85040034378 12 11 12780 12788 en ACS Nano © 2017 American Chemical Society. All rights reserved. |
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Engineering::Materials Vertically Stacked 2D Materials Growth Mechanisms Ye, Han Zhou, Jiadong Er, Dequan Price, Christopher C. Yu, Zhongyuan Liu, Yumin Lowengrub, John Lou, Jun Liu, Zheng Shenoy, Vivek B. Toward a mechanistic understanding of vertical growth of van der Waals stacked 2D materials : a multiscale model and experiments |
| description |
Vertical stacking of monolayers via van der Waals (vdW) interaction opens promising routes toward engineering physical properties of two-dimensional (2D) materials and designing atomically thin devices. However, due to the lack of mechanistic understanding, challenges remain in the controlled fabrication of these structures via scalable methods such as chemical vapor deposition (CVD) onto substrates. In this paper, we develop a general multiscale model to describe the size evolution of 2D layers and predict the necessary growth conditions for vertical (initial + subsequent layers) versus in-plane lateral (monolayer) growth. An analytic thermodynamic criterion is established for subsequent layer growth that depends on the sizes of both layers, the vdW interaction energies, and the edge energy of 2D layers. Considering the time-dependent growth process, we find that temperature and adatom flux from vapor are the primary criteria affecting the self-assembled growth. The proposed model clearly demonstrates the distinct roles of thermodynamic and kinetic mechanisms governing the final structure. Our model agrees with experimental observations of various monolayer and bilayer transition metal dichalcogenides grown by CVD and provides a predictive framework to guide the fabrication of vertically stacked 2D materials. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Ye, Han Zhou, Jiadong Er, Dequan Price, Christopher C. Yu, Zhongyuan Liu, Yumin Lowengrub, John Lou, Jun Liu, Zheng Shenoy, Vivek B. |
| format |
Article |
| author |
Ye, Han Zhou, Jiadong Er, Dequan Price, Christopher C. Yu, Zhongyuan Liu, Yumin Lowengrub, John Lou, Jun Liu, Zheng Shenoy, Vivek B. |
| author_sort |
Ye, Han |
| title |
Toward a mechanistic understanding of vertical growth of van der Waals stacked 2D materials : a multiscale model and experiments |
| title_short |
Toward a mechanistic understanding of vertical growth of van der Waals stacked 2D materials : a multiscale model and experiments |
| title_full |
Toward a mechanistic understanding of vertical growth of van der Waals stacked 2D materials : a multiscale model and experiments |
| title_fullStr |
Toward a mechanistic understanding of vertical growth of van der Waals stacked 2D materials : a multiscale model and experiments |
| title_full_unstemmed |
Toward a mechanistic understanding of vertical growth of van der Waals stacked 2D materials : a multiscale model and experiments |
| title_sort |
toward a mechanistic understanding of vertical growth of van der waals stacked 2d materials : a multiscale model and experiments |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/141465 |
| _version_ |
1681059065871990784 |