Enhanced metal-insulator transition in freestanding VO2 down to 5 nm thickness
Ultrathin freestanding membranes with a pronounced metal–insulator transition (MIT) have huge potential for future flexible electronic applications as well as provide a unique aspect for the study of lattice–electron interplay. However, the reduction of the thickness to an ultrathin region (a few nm...
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sg-ntu-dr.10356-1513932024-04-18T06:00:47Z Enhanced metal-insulator transition in freestanding VO2 down to 5 nm thickness Han, Kun Wu, Liang Cao, Yu Wang, Hanyu Ye, Chen Huang, Ke Motapothula, M. Xing, Hongna Li, Xinghua Qi, Dong-Chen Li, Xiao Wang, Renshaw Xiao School of Physical and Mathematical Sciences Science::Physics Vanadium Dioxide Metal-insulator Transition Ultrathin freestanding membranes with a pronounced metal–insulator transition (MIT) have huge potential for future flexible electronic applications as well as provide a unique aspect for the study of lattice–electron interplay. However, the reduction of the thickness to an ultrathin region (a few nm) is typically detrimental to the MIT in epitaxial films, and even catastrophic for their freestanding form. Here, we report an enhanced MIT in VO2-based freestanding membranes, with a lateral size up to millimeters and the VO2 thickness down to 5 nm. The VO2 membranes were detached by dissolving a Sr3Al2O6 sacrificial layer between the VO2 thin film and the c-Al2O3(0001) substrate, allowing the transfer onto arbitrary surfaces. Furthermore, the MIT in the VO2 membrane was greatly enhanced by inserting an intermediate Al2O3 buffer layer. In comparison with the best available ultrathin VO2 membranes, the enhancement of MIT is over 400% at a 5 nm VO2 thickness and more than 1 order of magnitude for VO2 above 10 nm. Our study widens the spectrum of functionality in ultrathin and large-scale membranes and enables the potential integration of MIT into flexible electronics and photonics. Ministry of Education (MOE) National Research Foundation (NRF) Accepted version 2021-06-13T12:50:00Z 2021-06-13T12:50:00Z 2021 Journal Article 1944-8252 https://hdl.handle.net/10356/151393 10.1021/acsami.1c01581 14 13 16688 16693 en ACS Applied Materials and Interfaces This document is the Accepted Manuscript version of a Published Work that appeared in final form in ACS Applied Materials and Interfaces, copyright © American Chemical Society after peer review and technical editing by the publisher. To access the final edited and published work see https://doi.org/10.1021/acsami.1c01581 application/pdf |
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Science::Physics Vanadium Dioxide Metal-insulator Transition |
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Science::Physics Vanadium Dioxide Metal-insulator Transition Han, Kun Wu, Liang Cao, Yu Wang, Hanyu Ye, Chen Huang, Ke Motapothula, M. Xing, Hongna Li, Xinghua Qi, Dong-Chen Li, Xiao Wang, Renshaw Xiao Enhanced metal-insulator transition in freestanding VO2 down to 5 nm thickness |
| description |
Ultrathin freestanding membranes with a pronounced metal–insulator transition (MIT) have huge potential for future flexible electronic applications as well as provide a unique aspect for the study of lattice–electron interplay. However, the reduction of the thickness to an ultrathin region (a few nm) is typically detrimental to the MIT in epitaxial films, and even catastrophic for their freestanding form. Here, we report an enhanced MIT in VO2-based freestanding membranes, with a lateral size up to millimeters and the VO2 thickness down to 5 nm. The VO2 membranes were detached by dissolving a Sr3Al2O6 sacrificial layer between the VO2 thin film and the c-Al2O3(0001) substrate, allowing the transfer onto arbitrary surfaces. Furthermore, the MIT in the VO2 membrane was greatly enhanced by inserting an intermediate Al2O3 buffer layer. In comparison with the best available ultrathin VO2 membranes, the enhancement of MIT is over 400% at a 5 nm VO2 thickness and more than 1 order of magnitude for VO2 above 10 nm. Our study widens the spectrum of functionality in ultrathin and large-scale membranes and enables the potential integration of MIT into flexible electronics and photonics. |
| author2 |
School of Physical and Mathematical Sciences |
| author_facet |
School of Physical and Mathematical Sciences Han, Kun Wu, Liang Cao, Yu Wang, Hanyu Ye, Chen Huang, Ke Motapothula, M. Xing, Hongna Li, Xinghua Qi, Dong-Chen Li, Xiao Wang, Renshaw Xiao |
| format |
Article |
| author |
Han, Kun Wu, Liang Cao, Yu Wang, Hanyu Ye, Chen Huang, Ke Motapothula, M. Xing, Hongna Li, Xinghua Qi, Dong-Chen Li, Xiao Wang, Renshaw Xiao |
| author_sort |
Han, Kun |
| title |
Enhanced metal-insulator transition in freestanding VO2 down to 5 nm thickness |
| title_short |
Enhanced metal-insulator transition in freestanding VO2 down to 5 nm thickness |
| title_full |
Enhanced metal-insulator transition in freestanding VO2 down to 5 nm thickness |
| title_fullStr |
Enhanced metal-insulator transition in freestanding VO2 down to 5 nm thickness |
| title_full_unstemmed |
Enhanced metal-insulator transition in freestanding VO2 down to 5 nm thickness |
| title_sort |
enhanced metal-insulator transition in freestanding vo2 down to 5 nm thickness |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/151393 |
| _version_ |
1800916295831519232 |