Reversible modulation of metal-insulator transition in VO₂ via chemically-induced oxygen migration
Metal-insulator transitions (MIT),an intriguing correlated phenomenon induced by the subtle competition of the electrons' repulsive Coulomb interaction and kinetic energy, is of great potential use for electronic applications due to the dramatic change in resistivity. Here, we demonstrate a...
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sg-ntu-dr.10356-1535592023-02-28T19:55:02Z Reversible modulation of metal-insulator transition in VO₂ via chemically-induced oxygen migration Han, Kun Wang, Hanyu Wu, Liang Cao, Yu Qi, Dong-Chen Li, Changjian Huang, Zhen Li, Xiao Wang, Renshaw Xiao School of Physical and Mathematical Sciences School of Electrical and Electronic Engineering Division of Physics and Applied Physics Science::Physics Engineering::Electrical and electronic engineering Aluminum Compounds Calculations Metal-insulator transitions (MIT),an intriguing correlated phenomenon induced by the subtle competition of the electrons' repulsive Coulomb interaction and kinetic energy, is of great potential use for electronic applications due to the dramatic change in resistivity. Here, we demonstrate a reversible control of MIT in VO2 films via oxygen stoichiometry engineering. By facilely depositing and dissolving a water-soluble yet oxygen-active Sr3Al2O6 capping layer atop the VO2 at room temperature, oxygen ions can reversibly migrate between VO2 and Sr3Al2O6, resulting in a gradual suppression and a complete recovery of MIT in VO2. The migration of the oxygen ions is evidenced in a combination of transport measurement, structural characterization and first-principles calculations. This approach of chemically-induced oxygen migration using a water-dissolvable adjacent layer could be useful for advanced electronic and iontronic devices and studying oxygen stoichiometry effects on the MIT. Agency for Science, Technology and Research (A*STAR) Ministry of Education (MOE) National Research Foundation (NRF) Published version X.R.W. acknowledges support from the Tier 2 (Grant No. MOE-T2EP50120-0006) and Tier 3 (Grant No. MOE2018-T3-1- 002) from Singapore Ministry of Education, the Singapore National Research Foundation (NRF) under the competitive Research Programs (CRP Grant No. NRF-CRP21-2018-0003), and the Agency for Science, Technology and Research (A STAR) under its AME IRG grant (Project No. A20E5c0094). L.W. acknowledges support from Foshan (Southern China) Institute for New Materials (No. 2021AYF25014). X.R.W. thanks Ke Huang, Ariando, and T. Venky Ventakesan for their help. Z.H. acknowledges the support from the National Natural Science Foundation of China (Grant No. 12074001). X.L. acknowledges support from the National Natural Science Foundation of China (Grant No. 11904173) and the Jiangsu Specially Appointed Professor. D.-C.Q. acknowledges the support of the Australian Research Council (Grant No. FT160100207). 2021-12-07T08:03:44Z 2021-12-07T08:03:44Z 2021 Journal Article Han, K., Wang, H., Wu, L., Cao, Y., Qi, D., Li, C., Huang, Z., Li, X. & Wang, R. X. (2021). Reversible modulation of metal-insulator transition in VO₂ via chemically-induced oxygen migration. Applied Physics Letters, 119(13), 133102-. https://dx.doi.org/10.1063/5.0058989 0003-6951 https://hdl.handle.net/10356/153559 10.1063/5.0058989 2-s2.0-85115918678 13 119 133102 en MOE-T2EP50120-0006 MOE2018-T3-1- 002 NRF-CRP21-2018-0003 A20E5c0094 Applied Physics Letters © 2021 Author(s). All rights reserved. This paper was published by AIP Publishing in Applied Physics Letters and is made available with permission of Author(s). application/pdf |
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Science::Physics Engineering::Electrical and electronic engineering Aluminum Compounds Calculations Han, Kun Wang, Hanyu Wu, Liang Cao, Yu Qi, Dong-Chen Li, Changjian Huang, Zhen Li, Xiao Wang, Renshaw Xiao Reversible modulation of metal-insulator transition in VO₂ via chemically-induced oxygen migration |
| description |
Metal-insulator transitions (MIT),an intriguing correlated phenomenon induced
by the subtle competition of the electrons' repulsive Coulomb interaction and
kinetic energy, is of great potential use for electronic applications due to
the dramatic change in resistivity. Here, we demonstrate a reversible control
of MIT in VO2 films via oxygen stoichiometry engineering. By facilely
depositing and dissolving a water-soluble yet oxygen-active Sr3Al2O6 capping
layer atop the VO2 at room temperature, oxygen ions can reversibly migrate
between VO2 and Sr3Al2O6, resulting in a gradual suppression and a complete
recovery of MIT in VO2. The migration of the oxygen ions is evidenced in a
combination of transport measurement, structural characterization and
first-principles calculations. This approach of chemically-induced oxygen
migration using a water-dissolvable adjacent layer could be useful for advanced
electronic and iontronic devices and studying oxygen stoichiometry effects on
the MIT. |
| author2 |
School of Physical and Mathematical Sciences |
| author_facet |
School of Physical and Mathematical Sciences Han, Kun Wang, Hanyu Wu, Liang Cao, Yu Qi, Dong-Chen Li, Changjian Huang, Zhen Li, Xiao Wang, Renshaw Xiao |
| format |
Article |
| author |
Han, Kun Wang, Hanyu Wu, Liang Cao, Yu Qi, Dong-Chen Li, Changjian Huang, Zhen Li, Xiao Wang, Renshaw Xiao |
| author_sort |
Han, Kun |
| title |
Reversible modulation of metal-insulator transition in VO₂ via chemically-induced oxygen migration |
| title_short |
Reversible modulation of metal-insulator transition in VO₂ via chemically-induced oxygen migration |
| title_full |
Reversible modulation of metal-insulator transition in VO₂ via chemically-induced oxygen migration |
| title_fullStr |
Reversible modulation of metal-insulator transition in VO₂ via chemically-induced oxygen migration |
| title_full_unstemmed |
Reversible modulation of metal-insulator transition in VO₂ via chemically-induced oxygen migration |
| title_sort |
reversible modulation of metal-insulator transition in vo₂ via chemically-induced oxygen migration |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/153559 |
| _version_ |
1759854580855734272 |