Classifiable Limiting Mass Change Detection in a Graphene Resonator Using Applied Machine Learning

Journal article (2022)

Authors

Miri Seo Ewha Womans University
Eunseo Yang Ewha Womans University
D. Shin Kavli institute of nanoscience Delft
Yugyeong Je Ewha Womans University
C. Joo Ewha Womans University, Kavli institute of nanoscience Delft, BN/Chirlmin Joo Lab - AS
Kookjin Lee Intel Labs
Sang Wook Lee Ewha Womans University
Research Group
BN/Chirlmin Joo Lab (AS) (TU Delft)
Copyright: © 2022 Miri Seo, Eunseo Yang, D. Shin, Yugyeong Je, C. Joo, Kookjin Lee, Sang Wook Lee
DOI: https://doi.org/10.1021/acsaelm.2c00628
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Published Date

2022

Language

English

Reuse Rights

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Faculty

Applied Sciences

Department

BN/Bionanoscience

Research Group

BN/Chirlmin Joo Lab

Abstract

Nanomechanical resonator devices are widely used as ultrasensitive mass detectors for fundamental studies and practical applications. The resonance frequency of the resonators shifts when a mass is loaded, which is used to estimate the mass. However, the shift signal is often blurred by the thermal noise, which interferes with accurate mass detection. Here, we demonstrate the reduction of the noise interference in mass detection in suspended graphene-based nanomechanical resonators, by using applied machine learning. Featurization is divided into image and sequential datasets, and those datasets are trained and classified using 2D and 1D convolutional neural networks (CNNs). The 2D CNN learning-based classification shows a performance with f1-score over 99% when the resonance frequency shift is more than 2.5% of the amplitude of the thermal noise range.

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