Machine Learning Enhanced Optical Microscopy for the Rapid Morphology Characterization of Silver Nanoparticles

Xu, Yaodong; Xu, Da; Yu, Ning; Liang, Boqun; Yang, Zhaoxi; Asif, M. Salman; Yan, Ruoxue; Liu, Ming

doi:10.1021/acsami.3c02448

“…In recent years, machine learning methods, which can identify features from the mass of data, have been broadly applied in chemical analysis, − image recognition, − disease prediction, − and material synthesis. − Specifically, the image data set with nonlinear, high-dimensional, and complicated data is hard to deal with via traditional statistical methods such as hierarchical cluster analysis (HCA), principal component analysis (PCA), or linear discriminant analysis (LDA). In contrast, deep learning algorithms are more suitable for analyzing nonlinear and multidimensional image data.…”

Section: Introductionmentioning

confidence: 99%

Holistic Prediction of AuNP Aggregation in Diverse Aqueous Suspensions Based on Machine Vision and Dark-Field Scattering Imaging

Wang,

Hong,

Zhou

et al. 2024

Anal. Chem.

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The localized surface-plasmon resonance of the AuNP in aqueous media is extremely sensitive to environmental changes. By measuring the signal of plasmon scattering light, the dark-field microscopic (DFM) imaging technique has been used to monitor the aggregation of AuNPs, which has attracted great attention because of its simplicity, low cost, high sensitivity, and universal applicability. However, it is still challenging to interpret DFM images of AuNP aggregation due to the heterogeneous characteristics of the isolated and discontinuous color distribution. Herein, we introduce machine vision algorithms for the training of DFM images of AuNPs in different saline aqueous media. A visual deep learning framework based on AlexNet is constructed for studying the aggregation patterns of AuNPs in aqueous suspensions, which allows for rapid and accurate identification of the aggregation extent of AuNPs, with a prediction accuracy higher than 0.96. With the aid of machine learning analysis, we further demonstrate the prediction ability of various aggregation phenomena induced by both cation species and the concentration of the external saline solution. Our results suggest the great potential of machine vision frameworks in the accurate recognition of subtle pattern changes in DFM images, which can help researchers build predictive analytics based on DFM imaging data.

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“…Additionally, SEM images contain a high degree of noise that impedes the performance of traditional classification methods 29 . Due to the large number of images, this process can benefit from automatization 30 , especially when the need to use a less resolved and time-consuming characterization method arises 31 .…”

Section: Introductionmentioning

confidence: 99%

Machine Learning Inspired Nanowire Classification Method based on Nanowire Array Scanning Electron Microscope Images

Brugnolotto,

Aleksandrov,

Sousa

et al. 2024

Open Res Europe

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Background This article introduces an innovative classification methodology to identify nanowires within scanning electron microscope images. Methods Our approach employs advanced image manipulation techniques in conjunction with machine learning-based recognition algorithms. The effectiveness of our proposed method is demonstrated through its application to the categorization of scanning electron microscopy images depicting nanowires arrays. Results The method’s capability to isolate and distinguish individual nanowires within an array is the primary factor in the observed accuracy. The foundational data set for model training comprises scanning electron microscopy images featuring 240 III-V nanowire arrays grown with metal organic chemical vapor deposition on silicon substrates. Each of these arrays consists of 66 nanowires. The results underscore the model’s proficiency in discerning distinct wire configurations and detecting parasitic crystals. Our approach yields an average F1 score of 0.91, indicating high precision and recall. Conclusions Such a high level of performance and accuracy of ML methods demonstrate the viability of our technique not only for academic but also for practical commercial implementation and usage.

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Machine Learning Inspired Nanowire Classification Method based on Nanowire Array Scanning Electron Microscope Images

Brugnolotto,

Aleksandrov,

Sousa

et al. 2024

Open Res Europe

1

0

View full text Add to dashboard Cite

Background This article introduces an innovative classification methodology to identify nanowires within scanning electron microscope images. Methods Our approach employs advanced image manipulation techniques in conjunction with machine learning-based recognition algorithms. The effectiveness of our proposed method is demonstrated through its application to the categorization of scanning electron microscopy images depicting nanowires arrays. Results The method’s capability to isolate and distinguish individual nanowires within an array is the primary factor in the observed accuracy. The foundational data set for model training comprises scanning electron microscopy images featuring 240 III-V nanowire arrays grown with metal organic chemical vapor deposition on silicon substrates. Each of these arrays consists of 66 nanowires. The results underscore the model’s proficiency in discerning distinct wire configurations and detecting parasitic crystals. Our approach yields an average F1 score of 0.91, indicating high precision and recall. Conclusions Such a high level of performance and accuracy of ML methods demonstrate the viability of our technique not only for academic but also for practical commercial implementation and usage.

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Machine Learning Enhanced Optical Microscopy for the Rapid Morphology Characterization of Silver Nanoparticles

Cited by 4 publications

References 40 publications

Holistic Prediction of AuNP Aggregation in Diverse Aqueous Suspensions Based on Machine Vision and Dark-Field Scattering Imaging

Holistic Prediction of AuNP Aggregation in Diverse Aqueous Suspensions Based on Machine Vision and Dark-Field Scattering Imaging

Machine Learning Inspired Nanowire Classification Method based on Nanowire Array Scanning Electron Microscope Images

Machine Learning Inspired Nanowire Classification Method based on Nanowire Array Scanning Electron Microscope Images

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