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Predicting the multiple parameters of organic acceptors through machine learning using <scp>RDkit</scp> descriptors: An easy and fast pipeline

Khadijah Mohammedsaleh Katubi, Muhammad Saqib, Tayyaba Mubashir, Mudassir Hussain Tahir, Mohamed Ibrahim Halawa, Alveena Akbar, Beriham Basha, Muhammad Sulaman, Z.A. Alrowaili, M.S. Al-Buriahi

2023International Journal of Quantum Chemistry21 citationsDOIOpen Access PDF

Abstract

Abstract Machine learning (ML) analysis has gained huge importance among researchers for predicting multiple parameters and designing efficient donor and acceptor materials without experimentation. Data are collected from literature and subsequently used for predicting impactful properties of organic solar cells such as power conversion efficiency (PCE) and energy levels (HOMO/LUMO). Importantly, out of various tested models, hist gradient boosting (HGB) and the light gradient boosting (LGBM) regression models revealed better predictive capabilities. To achieve the prediction effectively, the selected (best) ML regression models are further tuned. For the prediction of PCE (test set), the LGBM shows the coefficient of determination ( R 2 ) value of 0.787, which is higher than HGB ( R 2 = 0.680). For the prediction of HOMO (test set), the LGBM shows R 2 value of 0.566, which is higher than HGB ( R 2 = 0.563). However, for the prediction of LUMO (test set), the LGBM shows R 2 value of 0.605, which is lower than HGB ( R 2 = 0.606). Among the three predicted properties, prediction ability is higher for PCE. These models help to predict the efficient acceptors in a short time and less computational cost.

Topics & Concepts

Boosting (machine learning)Gradient boostingTest setPipeline (software)Computer scienceArtificial intelligenceLinear regressionRegression analysisHOMO/LUMORegressionAcceptorMachine learningMathematicsChemistryStatisticsPhysicsMoleculeProgramming languageRandom forestCondensed matter physicsOrganic chemistryOrganic Electronics and PhotovoltaicsConducting polymers and applicationsMachine Learning in Materials Science