Predicting the maximum absorption wavelength of azo dyes using an interpretable machine learning strategy

Mai, Jiaqi; Liu, Tian; Xu, Pengcheng; Lian, Zhengheng; Li, Minjie; Lu, Wencong

doi:10.1016/j.dyepig.2022.110647

Cited by 21 publications

(6 citation statements)

References 49 publications

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“…The three major scenarios of model application are high-throughput screening (HTS), inverse design, and the development of online prediction programs. HTS uses the constructed model to predict the target variables of a huge number of virtual samples in order to filter out samples with high performance potential and guide experimental synthesis [29,30]. The inverse design can be used to obtain the features of designed samples via the inverse projection method, which is an effective way to realize the material from properties to composition [31,32].…”

Section: Workflow Of Materials Machine Learningmentioning

confidence: 99%

Feature Selection in Machine Learning for Perovskite Materials Design and Discovery

Wang

et al. 2023

Materials

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Perovskite materials have been one of the most important research objects in materials science due to their excellent photoelectric properties as well as correspondingly complex structures. Machine learning (ML) methods have been playing an important role in the design and discovery of perovskite materials, while feature selection as a dimensionality reduction method has occupied a crucial position in the ML workflow. In this review, we introduced the recent advances in the applications of feature selection in perovskite materials. First, the development tendency of publications about ML in perovskite materials was analyzed, and the ML workflow for materials was summarized. Then the commonly used feature selection methods were briefly introduced, and the applications of feature selection in inorganic perovskites, hybrid organic-inorganic perovskites (HOIPs), and double perovskites (DPs) were reviewed. Finally, we put forward some directions for the future development of feature selection in machine learning for perovskite material design.

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Section: Workflow Of Materials Machine Learningmentioning

confidence: 99%

Feature Selection in Machine Learning for Perovskite Materials Design and Discovery

Wang

et al. 2023

Materials

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“…XGBoost [97] IR and Raman spectra Predict surface-adsorbate interaction properties ET, [98] SISSO [98] Synthesis Selected synthesis descriptors Classify selected features of spectra ET [99] The citrate to gold (III) ratio, scanning velocity and radiation intensity Predict nanoparticle size ANN [ 100] Spectroscopic characteristics based on UV-vis/DLS Optimize experimental/reaction conditions GA, [ 101] BO+DNN [ 102] Reaction conditions Predict selected spectroscopic characteristics of nanoparticles SVR [103] Target molecules Propose a sequence of chemically viable reaction steps ANN [ 104] Instrumentations and spectral preprocessing Complex 2D images Optimize illumination light source parameters CNN [ 105] Patterns of weakly scattering perturbations Design transmission matrices VAE [ 106] Scattering spectra of nanostructures Encode up to 9 bits of information for high-density optical information storage CNN [ 107] Noisy Raman spectra Remove the baseline, cosmic rays, and noise simultaneously or separately CNN, [108][109][110] ResNet, [ 111] U-net, [ 111] ANN+U-net, [ 112] PCA, [113] GAN [ 114] Spectral analysis SERS spectrum Identify the existence of the molecular fingerprints…”

Section: Molecular Graphmentioning

confidence: 99%

“…and Mai et al applied XGBoost to predict the maximum absorption wavelength of azo dyes and incorporated SHAP to explain the relationship between the molecular structure and the absorption, [97] both exhibiting the potential in screening suitable molecules upon certain incident wavelength and/or substrate plasmonic on-resonance wavelength. When taking the whole SERS nanotag into consideration, Wang et al leveraged AI to further solve the interaction properties of substrate-adsorbate systems, including adsorption energy, charge transfer, and molecular bond energy, [98] exerting high potential in reducing redundant manual trials and designing high-performance nanotags with reporter molecules meeting criteria of high absorption, large cross section, and efficient charge transfer.…”

Section: Variant Characteristicsmentioning

confidence: 99%

“…Specifically, the resonance of the reporter molecules, the charge transfer between the reporters and the SERS substrates, as well as the on‐resonance EM enhancement of the SERS substrates can be coupled within one SERS nanotag to give rise to ultra‐strong signals (i.e., λ reporter ≈ λ substrate ≈ λ charge transfer ≈ λ incidence ). [ 210 ] Though it is hard for conventional wisdoms to tackle such intertwining problems, in terms of the fluorescence molecules only, Joung et al used a DL model to solve the properties of fluorescence including absorption and emission peak wavelengths in different solvents, [ 188 ] and Mai et al applied XGBoost to predict the maximum absorption wavelength of azo dyes and incorporated SHAP to explain the relationship between the molecular structure and the absorption, [ 97 ] both exhibiting the potential in screening suitable molecules upon certain incident wavelength and/or substrate plasmonic on‐resonance wavelength. When taking the whole SERS nanotag into consideration, Wang et al leveraged AI to further solve the interaction properties of substrate‐adsorbate systems, including adsorption energy, charge transfer, and molecular bond energy, [ 98 ] exerting high potential in reducing redundant manual trials and designing high‐performance nanotags with reporter molecules meeting criteria of high absorption, large cross section, and efficient charge transfer.…”

Section: Ai For Selection and Design Of Sers Reportersmentioning

confidence: 99%

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Artificial Intelligence for Surface‐Enhanced Raman Spectroscopy

Bi,

Lin,

Chen

et al. 2023

Small Methods

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Surface‐enhanced Raman spectroscopy (SERS), well acknowledged as a fingerprinting and sensitive analytical technique, has exerted high applicational value in a broad range of fields including biomedicine, environmental protection, food safety among the others. In the endless pursuit of ever‐sensitive, robust, and comprehensive sensing and imaging, advancements keep emerging in the whole pipeline of SERS, from the design of SERS substrates and reporter molecules, synthetic route planning, instrument refinement, to data preprocessing and analysis methods. Artificial intelligence (AI), which is created to imitate and eventually exceed human behaviors, has exhibited its power in learning high‐level representations and recognizing complicated patterns with exceptional automaticity. Therefore, facing up with the intertwining influential factors and explosive data size, AI has been increasingly leveraged in all the above‐mentioned aspects in SERS, presenting elite efficiency in accelerating systematic optimization and deepening understanding about the fundamental physics and spectral data, which far transcends human labors and conventional computations. In this review, the recent progresses in SERS are summarized through the integration of AI, and new insights of the challenges and perspectives are provided in aim to better gear SERS toward the fast track.

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“…However, the complexity of excited state PESs and the relevant computational cost often hinder the theoretical explorations on these novel molecular properties. Consequently, developing the efficient and reliable computational tools to assess the experimental observables became an increasing interest for the applications like molecular chromophores, − organic solar cell, ,,− photoswitch, and optical materials , by the computational chemistry community.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Predictions for the Experimental Photophysical Data Using the Featurized Schnet-Bondstep Approach

Hung

Cheng

et al. 2023

J. Chem. Theory Comput.

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An assessment of modifying the SchNET model for the predictions of experimental molecular photophysical properties, including absorption energy (ΔE abs), emission energy (ΔE emi), and photoluminescence quantum yield (PLQY), was reported. The solution environment was properly introduced outside the interaction layers of SchNET for not overly amplifying the solute–solvent interactions, particularly being supported by the changes of prediction errors between the presence and absence of the solvent effect. Two featurization schemes under the framework of the Schnet-bondstep approach, with featuring the concepts of reduced-atomic-number and reduced-atomic-neighbor, were demonstrated. These featurized models can consequently provide fine predictions for ΔE abs and ΔE emi with errors less than 0.1 eV. The corresponding predictions of PLQY were shown to be comparable to the previous graph convolution network model.

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Predicting the maximum absorption wavelength of azo dyes using an interpretable machine learning strategy

Cited by 21 publications

References 49 publications

Feature Selection in Machine Learning for Perovskite Materials Design and Discovery

Feature Selection in Machine Learning for Perovskite Materials Design and Discovery

Artificial Intelligence for Surface‐Enhanced Raman Spectroscopy

Enhanced Predictions for the Experimental Photophysical Data Using the Featurized Schnet-Bondstep Approach

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