Hybrid Machine Learning for Scanning Near-field Optical Spectroscopy

The underlying physics behind an experimental observation often lacks a simple analytical description. This is especially the case for scanning probe microscopy techniques, where the interaction between the probe and the sample is nontrivial. Realistic modeling to include the details of the probe is...

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Veröffentlicht in:	arXiv.org 2021-05
Hauptverfasser:	Chen, Xinzhong, Yao, Ziheng, Xu, Suheng, McLeod, A S, Gilbert Corder, Stephanie N, Zhao, Yueqi, Tsuneto, Makoto, Bechtel, Hans A, Martin, Michael C, Carr, G L, Fogler, M M, Stanciu, Stefan G, Basov, D N, Liu, Mengkun
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Schlagworte:	Artificial neural networks Machine learning Material properties Microscopes Microscopy Near field optical microscopes Neural networks Optical microscopes Physics - Data Analysis, Statistics and Probability Physics - Instrumentation and Detectors Physics - Optics Scanning probe microscopy
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creator	Chen, Xinzhong Yao, Ziheng Xu, Suheng McLeod, A S Gilbert Corder, Stephanie N Zhao, Yueqi Tsuneto, Makoto Bechtel, Hans A Martin, Michael C Carr, G L Fogler, M M Stanciu, Stefan G Basov, D N Liu, Mengkun
description	The underlying physics behind an experimental observation often lacks a simple analytical description. This is especially the case for scanning probe microscopy techniques, where the interaction between the probe and the sample is nontrivial. Realistic modeling to include the details of the probe is always exponentially more difficult than its "spherical cow" counterparts. On the other hand, a well-trained artificial neural network based on real data can grasp the hidden correlation between the signal and sample properties. In this work, we show that, via a combination of model calculation and experimental data acquisition, a physics-infused hybrid neural network can predict the tip-sample interaction in the widely used scattering-type scanning near-field optical microscope. This hybrid network provides a long-sought solution for accurate extraction of material properties from tip-specific raw data. The methodology can be extended to other scanning probe microscopy techniques as well as other data-oriented physical problems in general.
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This is especially the case for scanning probe microscopy techniques, where the interaction between the probe and the sample is nontrivial. Realistic modeling to include the details of the probe is always exponentially more difficult than its "spherical cow" counterparts. On the other hand, a well-trained artificial neural network based on real data can grasp the hidden correlation between the signal and sample properties. In this work, we show that, via a combination of model calculation and experimental data acquisition, a physics-infused hybrid neural network can predict the tip-sample interaction in the widely used scattering-type scanning near-field optical microscope. This hybrid network provides a long-sought solution for accurate extraction of material properties from tip-specific raw data. 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subjects	Artificial neural networks Machine learning Material properties Microscopes Microscopy Near field optical microscopes Neural networks Optical microscopes Physics - Data Analysis, Statistics and Probability Physics - Instrumentation and Detectors Physics - Optics Scanning probe microscopy
title	Hybrid Machine Learning for Scanning Near-field Optical Spectroscopy
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