What question did this study set out to answer?

The research aims to explore the metal-insulator transition in ultrathin VO2 nanosheets and address performance limitations due to substrate strain.

January 25, 2026

Two-Dimensional Metal–Insulator Transition in Ultrathin VO 2 Nanosheets via Remote van der Waals Epitaxy

Key Points

The research aims to explore the metal-insulator transition in ultrathin VO2 nanosheets and address performance limitations due to substrate strain.
Growth of few-nanometer-thick VO2 nanosheets via remote van der Waals epitaxy.
Characterization of crystal structure using transmission electron microscopy.
Evaluation of electrical properties through conductive atomic force microscopy measurements.
Confirmed monoclinic (M1) crystal structure in the ultrathin VO2 nanosheets.
Achieved complete onset of 2D metal-insulator transition at 1.5 V.
Attained an on/off ratio of nearly 10^4 in the electrical behavior of the nanosheets.

Abstract

Vanadium dioxide (VO2) undergoes a rutile-to-monoclinic metal-insulator transition (MIT) at 340 K. Marked by abrupt resistivity changes of 104-105 Ω·cm, this property has long attracted interest for electronic applications. However, when VO2 is a few nanometers thick, substrate-induced strain destabilizes the MIT, which limits device performance. To overcome this, two-dimensional (2D) VO2 nanostructures grown with a remote distance from substrates can reveal intrinsic strain-free electrical behavior and enable high-performance MIT-based devices. We report the growth of few-nanometer-thick 2D VO2 via remote van der Waals epitaxy. Transmission electron microscopy confirmed the monoclinic (M1) crystal structure. Conductive atomic force microscopy (c-AFM) measurements demonstrated a complete onset of 2D MIT at 1.5 V, achieving an on/off ratio of nearly 104.

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Two-Dimensional Metal–Insulator Transition in Ultrathin VO 2 Nanosheets via Remote van der Waals Epitaxy

Key Points

Abstract

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