Artificially controlled nanoscale chemical reduction in VO2 through electron beam illumination

Zhang, Yang; Wang, Yupu; Wu, Yongshun; Shu, Xinyu; Zhang, Fan; Peng, Huining; Shen, Shengchun; Ogawa, Naoki; Zhu, Junyi; Yu, Pu

Artificially controlled nanoscale chemical reduction in VO2 through electron beam illumination

Yang Zhang, Yupu Wang, Yongshun Wu, Xinyu Shu, Fan Zhang, Huining Peng, Shengchun Shen, Naoki Ogawa, Junyi Zhu () and Pu Yu ()
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Yang Zhang: Tsinghua University
Yupu Wang: The Chinese University of Hong Kong
Yongshun Wu: Tsinghua University
Xinyu Shu: Tsinghua University
Fan Zhang: Tsinghua University
Huining Peng: Tsinghua University
Shengchun Shen: Tsinghua University
Naoki Ogawa: RIKEN Center for Emergent Matter Science (CEMS)
Junyi Zhu: The Chinese University of Hong Kong
Pu Yu: Tsinghua University

Nature Communications, 2023, vol. 14, issue 1, 1-8

Abstract: Abstract Chemical reduction in oxides plays a crucial role in engineering the material properties through structural transformation and electron filling. Controlling the reduction at nanoscale forms a promising pathway to harvest functionalities, which however is of great challenge for conventional methods (e.g., thermal treatment and chemical reaction). Here, we demonstrate a convenient pathway to achieve nanoscale chemical reduction for vanadium dioxide through the electron-beam illumination. The electron beam induces both surface oxygen desorption through radiolytic process and positively charged background through secondary electrons, which contribute cooperatively to facilitate the vacancy migration from the surface toward the sample bulk. Consequently, the VO2 transforms into a reduced V2O3 phase, which is associated with a distinct insulator to metal transition at room temperature. Furthermore, this process shows an interesting facet-dependence with the pronounced transformation observed for the c-facet VO2 as compared with the a-facet, which is attributed to the intrinsically different oxygen vacancy formation energy between these facets. Remarkably, we readily achieve a lateral resolution of tens nanometer for the controlled structural transformation with a commercial scanning electron microscope. This work provides a feasible strategy to manipulate the nanoscale chemical reduction in complex oxides for exploiting functionalities.

Date: 2023
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DOI: 10.1038/s41467-023-39812-8

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