Screening and designing of a large chemical space of organic semiconductors for photodetectors

The computational approaches show immense potential for rapid discovery, screening, and rational designing of high-performance materials with tailored properties by providing guidance about candidate material for synthesis. Machine learning, an artificial intelligence technology-based approach, prov...

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Bibliographic Details
Published in:Materials today communications 2024-03, Vol.38, p.108062, Article 108062
Main Authors: Saqib, Muhammad, Sagir, Muhammad, Joshi, Munawar Lal, Bashir, Shahida, Halawa, Mohamed Ibrahim, Ali, Saman, Elansary, Hosam O., Kamal, Ghulam Mustafa
Format: Article
Language:English
Subjects:
Chemical space
Clustering
Machine learning
Photodetector
Similarity analysis
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Summary:The computational approaches show immense potential for rapid discovery, screening, and rational designing of high-performance materials with tailored properties by providing guidance about candidate material for synthesis. Machine learning, an artificial intelligence technology-based approach, provides efficient exploration of high throughput materials as compared to expensive quantum chemical calculations. In this work, machine learning is applied to screen large chemical space of organic semiconductors for aiding the material designing for photodetectors. The key parameters such as band gap and UV/visible absorption maxima of organic semiconductors, which can strongly affect their photodetector properties are predicted using trained machine learning models. Importantly, the hist gradient boosting regression model shows good predictive capability. The Breaking Retrosynthetically Interesting Chemical Substructures (BRICS) method is used to design 10,000 monomers using RDkit. Moreover, the clustering of monomers in generated chemical space is performed. In addition, Silhouette plot and t-distributed stochastic neighbor embedding (t-SNE) are constructed for complex data analysis and visualization. Property prediction is also conducted by considering crucial parameters of different monomers including band gaps, λmax, and synthetic accessibility scores. Similarity analysis is also performed using clustering of monomers and constructing heatmap of similarity in monomers. This methodology may help experimentalists select attractive synthetic targets, which may accelerate the development of photodetectors. [Display omitted] •Machine learning assisted screening a large chemical space of organic semiconductors for photodetectors is achieved.•BRICS method is used to design about 10,000 potential monomers for photodetectors.•The key parameters of organic semiconductors for photodetectors are predicted.•Regression analysisis used for complex data analysis and visualization.•Similarity analysis is applied using clustering method and heatmaps.
ISSN:2352-4928
2352-4928
DOI:10.1016/j.mtcomm.2024.108062