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Electric field-assisted resonance frequency tuning in free standing nanomechanical devices for application in multistate switching using a phase change material.

Authors :
Banswar D
Anand JK
Bukhari SA
Singh S
Prajesh R
Kumar H
Makineni SK
Goswami A
Source :
Nanoscale horizons [Nanoscale Horiz] 2024 Nov 06. Date of Electronic Publication: 2024 Nov 06.
Publication Year :
2024
Publisher :
Ahead of Print

Abstract

VO <subscript>2</subscript> possesses a unique property of solid-state phase transition near room temperature wherein it transforms from monoclinic (M1) to tetragonal phase (R) that alters its physical properties, such as resistivity, mechanical modulus, and lattice strain, at an ultrafast time scale known as MIT. Such a phenomenon offers a distinct advantage to use VO <subscript>2</subscript> in switching applications using heat flux as a stimulus. However, such alteration in properties can also be triggered under an electric field ( E ), which is known as E-MIT. A nanomechanical resonator coated with VO <subscript>2</subscript> recently received traction where the resonance behavior can be modulated by taking advantage of its phase transition. Herein, we demonstrate that by fabricating a microstring of 400 μm ( L ) × 5 μm ( W ) × 240 nm ( t ) of suspended SiN <subscript> x </subscript> coated with VO <subscript>2</subscript> , the frequency ( f <subscript>r</subscript> ) of the resonator can be modulated by applying an electric field. We show that at room temperature, the f <subscript>r</subscript> of the microstring can be either reduced (by 0.5% at 15 V mm <superscript>-1</superscript> ) or enhanced (by 2.2% at 25 V mm <superscript>-1</superscript> ) or can be varied in a cycle under E -field. Using theoretical models, we establish the simulated results and explain the processes behind it, which demonstrate excellent mechanical tuning properties of the VO <subscript>2</subscript> -based microstring resonator, making it an attractive and alternative option for highly efficient MEMS-based switches and neuromorphic devices.

Details

Language :
English
ISSN :
2055-6764
Database :
MEDLINE
Journal :
Nanoscale horizons
Publication Type :
Academic Journal
Accession number :
39501974
Full Text :
https://doi.org/10.1039/d4nh00463a