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Exploration and Design of Carbon Dot-Based Long Afterglow Materials Using Active Machine Learning and Quantum Chemical Simulations

Hongwei Yang, Zhun Ran, Yimeng Luo, Siyuan Liu, Weizhe Xu, Jinkun Liu, Jianghu Cui, Bingfu Lei, Chaofan Hu, Jianle Zhuang, Yingliang Liu, Yong Xiao

2024ACS Nano21 citationsDOI

Abstract

Long afterglow materials based on carbon dots (CDs) have attracted extensive attention in the field of optics due to their low cost and nontoxic properties. However, the targeted synthesis of specific properties of complex and unknown structures such as CDs remains a daunting challenge. In this study, the powerful nonlinear fitting ability of machine learning was used to explore the afterglow properties of CDs. The XGBoost algorithm demonstrates high prediction accuracy in determining the optimal excitation wavelength, optimal emission wavelength, and afterglow lifetime. Using Bayesian optimization, we screened and synthesized the CDs-based long afterglow materials with the longest lifetime reported so far by a one-step microwave method. By combining quantum chemical calculations with experimental data, we revealed the structure-function relationship between CDs and their precursors through electron-hole analysis. These results show that machine learning can establish nonlinear correlations between precursors and materials with unknown structures, clarify their intrinsic relationships, simplify the material design process, and thus accelerate the development of advanced materials.

Topics & Concepts

AfterglowQuantum dotQuantum chemicalCarbon quantum dotsCarbon fibersMaterials scienceNanotechnologyActive learning (machine learning)Active carbonComputer sciencePhysicsArtificial intelligenceEnvironmental scienceMoleculeQuantum mechanicsComposite materialComposite numberGamma-ray burstEnvironmental protectionCarbon and Quantum Dots ApplicationsLuminescence and Fluorescent MaterialsNanocluster Synthesis and Applications
Exploration and Design of Carbon Dot-Based Long Afterglow Materials Using Active Machine Learning and Quantum Chemical Simulations | Litcius