Litcius/Paper detail

Hybrid data-driven and physics-based modeling for viscosity prediction of ionic liquids

Jing Fan, Zhengxing Dai, Jian Cao, Liwen Mu, Xiaoyan Ji, Xiaohua Lü

2024Green Energy & Environment13 citationsDOIOpen Access PDF

Abstract

Viscosity is one of the most important fundamental properties of fluids. However, accurate acquisition of viscosity for ionic liquids (ILs) remains a critical challenge. In this study, an approach integrating prior physical knowledge into the machine learning (ML) model was proposed to predict the viscosity reliably. The method was based on 16 quantum chemical descriptors determined from the first principles calculations and used as the input of the ML models to represent the size, structure, and interactions of the ILs. Three strategies based on the residuals of the COSMO-RS model were created as the output of ML, where the strategy directly using experimental data was also studied for comparison. The performance of six ML algorithms was compared in all strategies, and the CatBoost model was identified as the optimal one. The strategies employing the relative deviations were superior to that using the absolute deviation, and the relative ratio revealed the systematic prediction error of the COSMO-RS model. The CatBoost model based on the relative ratio achieved the highest prediction accuracy on the test set (R2 = 0.9999, MAE = 0.0325), reducing the average absolute relative deviation (AARD) in modeling from 52.45% to 1.54%. Features importance analysis indicated the average energy correction, solvation-free energy, and polarity moment were the key influencing the systematic deviation.

Topics & Concepts

Approximation errorRelative standard deviationViscosityIonic liquidStandard deviationAbsolute deviationSolvationMoment (physics)Mean absolute errorSet (abstract data type)COSMO-RSComputer scienceBiological systemMaterials scienceThermodynamicsMathematicsChemistryAlgorithmMean squared errorStatisticsPhysicsMoleculeBiologyBiochemistryOrganic chemistryCatalysisClassical mechanicsProgramming languageDetection limitIonic liquids properties and applicationsElectrochemical Analysis and ApplicationsAdvanced Chemical Sensor Technologies