Creating 3D nanoparticle structural space via data augmentation to bidirectionally predict nanoparticle mixture’s purity, size, and shape from extinction spectra
Nanoparticle (NP) characterization is essential because diverse shapes, sizes, and morphologies inevitably occur in as-synthesized NP mixtures, profoundly impacting their properties and applications. Currently, the only technique to concurrently determine these structural parameters is electron micr...
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sg-ntu-dr.10356-1758602024-05-08T05:11:00Z Creating 3D nanoparticle structural space via data augmentation to bidirectionally predict nanoparticle mixture’s purity, size, and shape from extinction spectra Tan, Emily Xi Tang, Jingxiang Leong, Yong Xiang Phang, In Yee Lee, Yih Hong Pun, Chi Seng Ling, Xing Yi School of Chemistry, Chemical Engineering and Biotechnology School of Physical and Mathematical Sciences Chemistry Silvernanocubes Nanocharacterization Nanoparticle (NP) characterization is essential because diverse shapes, sizes, and morphologies inevitably occur in as-synthesized NP mixtures, profoundly impacting their properties and applications. Currently, the only technique to concurrently determine these structural parameters is electron microscopy, but it is time-intensive and tedious. Here, we create a three-dimensional (3D) NP structural space to concurrently determine the purity, size, and shape of 1000 sets of as-synthesized Ag nanocubes mixtures containing interfering nanospheres and nanowires from their extinction spectra, attaining low predictive errors at 2.7-7.9 %. We first use plasmonically-driven feature enrichment to extract localized surface plasmon resonance attributes from spectra and establish a lasso regressor (LR) model to predict purity, size, and shape. Leveraging the learned LR, we artificially generate 425,592 augmented extinction spectra to overcome data scarcity and create a comprehensive NP structural space to bidirectionally predict extinction spectra from structural parameters with <4 % error. Our interpretable NP structural space further elucidates the two higher-order combined electric dipole, quadrupole, and magnetic dipole as the critical structural parameter predictors. By incorporating other NP shapes and mixtures' extinction spectra, we anticipate our approach, especially the data augmentation, can create a fully generalizable NP structural space to drive on-demand, autonomous synthesis-characterization platforms. Agency for Science, Technology and Research (A*STAR) Ministry of Education (MOE) National Research Foundation (NRF) This research is supported by Singapore National Research Foundation Central Gap Fund (NRF2020NRF-CG001-010), Competitive Research Programme (NRF-CRP26-2021- 0002), National Research Foundation Investigators (NRFNRFI08-2022-0011), and A*STAR AME Individual Research Grant (A20E5c0082). C.S.P gratefully acknowledges the Ministry of Education (MOE) AcRF Tier 2 grant (Reference No: MOE-T2EP20220-0013) for funding this research. 2024-05-08T05:11:00Z 2024-05-08T05:11:00Z 2024 Journal Article Tan, E. X., Tang, J., Leong, Y. X., Phang, I. Y., Lee, Y. H., Pun, C. S. & Ling, X. Y. (2024). Creating 3D nanoparticle structural space via data augmentation to bidirectionally predict nanoparticle mixture’s purity, size, and shape from extinction spectra. Angewandte Chemie (International Ed. in English), 63(14), e202317978-. https://dx.doi.org/10.1002/anie.202317978 1433-7851 https://hdl.handle.net/10356/175860 10.1002/anie.202317978 38357744 2-s2.0-85186177376 14 63 e202317978 en NRF2020NRF-CG001-010 NRF-CRP26-2021-0002 NRF-NRFI08-2022-0011 A20E5c0082 MOE-T2EP20220-0013 Angewandte Chemie (International ed. in English) © 2024 Wiley-VCH GmbH. All rights reserved. |
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Chemistry Silvernanocubes Nanocharacterization Tan, Emily Xi Tang, Jingxiang Leong, Yong Xiang Phang, In Yee Lee, Yih Hong Pun, Chi Seng Ling, Xing Yi Creating 3D nanoparticle structural space via data augmentation to bidirectionally predict nanoparticle mixture’s purity, size, and shape from extinction spectra |
| description |
Nanoparticle (NP) characterization is essential because diverse shapes, sizes, and morphologies inevitably occur in as-synthesized NP mixtures, profoundly impacting their properties and applications. Currently, the only technique to concurrently determine these structural parameters is electron microscopy, but it is time-intensive and tedious. Here, we create a three-dimensional (3D) NP structural space to concurrently determine the purity, size, and shape of 1000 sets of as-synthesized Ag nanocubes mixtures containing interfering nanospheres and nanowires from their extinction spectra, attaining low predictive errors at 2.7-7.9 %. We first use plasmonically-driven feature enrichment to extract localized surface plasmon resonance attributes from spectra and establish a lasso regressor (LR) model to predict purity, size, and shape. Leveraging the learned LR, we artificially generate 425,592 augmented extinction spectra to overcome data scarcity and create a comprehensive NP structural space to bidirectionally predict extinction spectra from structural parameters with <4 % error. Our interpretable NP structural space further elucidates the two higher-order combined electric dipole, quadrupole, and magnetic dipole as the critical structural parameter predictors. By incorporating other NP shapes and mixtures' extinction spectra, we anticipate our approach, especially the data augmentation, can create a fully generalizable NP structural space to drive on-demand, autonomous synthesis-characterization platforms. |
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School of Chemistry, Chemical Engineering and Biotechnology |
| author_facet |
School of Chemistry, Chemical Engineering and Biotechnology Tan, Emily Xi Tang, Jingxiang Leong, Yong Xiang Phang, In Yee Lee, Yih Hong Pun, Chi Seng Ling, Xing Yi |
| format |
Article |
| author |
Tan, Emily Xi Tang, Jingxiang Leong, Yong Xiang Phang, In Yee Lee, Yih Hong Pun, Chi Seng Ling, Xing Yi |
| author_sort |
Tan, Emily Xi |
| title |
Creating 3D nanoparticle structural space via data augmentation to bidirectionally predict nanoparticle mixture’s purity, size, and shape from extinction spectra |
| title_short |
Creating 3D nanoparticle structural space via data augmentation to bidirectionally predict nanoparticle mixture’s purity, size, and shape from extinction spectra |
| title_full |
Creating 3D nanoparticle structural space via data augmentation to bidirectionally predict nanoparticle mixture’s purity, size, and shape from extinction spectra |
| title_fullStr |
Creating 3D nanoparticle structural space via data augmentation to bidirectionally predict nanoparticle mixture’s purity, size, and shape from extinction spectra |
| title_full_unstemmed |
Creating 3D nanoparticle structural space via data augmentation to bidirectionally predict nanoparticle mixture’s purity, size, and shape from extinction spectra |
| title_sort |
creating 3d nanoparticle structural space via data augmentation to bidirectionally predict nanoparticle mixture’s purity, size, and shape from extinction spectra |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/175860 |
| _version_ |
1800916345186942976 |