Research progress in phase transition of vanadium dioxide
ﬁlms driven by ultrafast optical ﬁeld

doi:10.3969/j.issn.1007-5461.2023.02.006

Abstract

Abstract: Vanadium dioxide (VO2) is an archetypal strongly correlated-electron material. When the phase transition threshold is reached, there will be a reversible transition from the insulating monoclinic phase to the metallic rutile phase for VO2. The transition can be induced mainly by thermal, optical, electrical, magnetic ﬁeld, and strain. The abrupt change of VO2 phase can occur in subpicosecond time scales, along with the signiﬁcant change of optical reﬂectivity, refractive index, magnetic susceptibility, and other physical quantities. In particular, the resistivity of VO2 will change in three to ﬁve orders of magnitude before and after the phase change, which makes VO2 has great application prospects in the ﬁelds of intelligent energy-saving windows, photoelectric detection, photoelectric storage, optical switches, and other ﬁelds. This review ﬁrst describes the phase transitions mechanism of VO2, which is driven by the electron correlation or the lattice structure alone or both. Then it focuses on employing ultrafast time-resolved techniques, particularly terahertz time-domain spectroscopy techniques, to study the phase transition dynamics process of VO2 thin ﬁlms. Finally, the application research of terahertz modulators, terahertz ﬁlters, terahertz switches, and other devices based on VO2 thin ﬁlms are introduced.

Key words: thin ?lm physics, vanadium dioxide thin ?lm, insulator-metal transition, terahertz time-domain spectroscopy, terahertz functional device

CLC Number:

O484.4

WANG Kang , , LIU Yi , SONG Liwei ∗. Research progress in phase transition of vanadium dioxide ﬁlms driven by ultrafast optical ﬁeld[J]. Chinese Journal of Quantum Electronics, 2023, 40(2): 238-257.

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Research progress in phase transition of vanadium dioxide ﬁlms driven by ultrafast optical ﬁeld

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